161 |
Tube yarn feeding apparatus in automatic winder |
JP9208177 |
1977-07-29 |
JPS5427037A |
1979-03-01 |
MATSUI ISAMU; SUGANUMA TAKEO |
|
162 |
Apparatus for determining direction of bottle |
JP982778 |
1978-01-31 |
JPS53121363A |
1978-10-23 |
AREKUSANDORU DEII IONESUKU |
|
163 |
JPS5211105B2 - |
JP9192974 |
1974-08-09 |
JPS5211105B2 |
1977-03-29 |
|
|
164 |
Shinamonorenzokukyokyusochi |
JP2872775 |
1975-03-11 |
JPS515188A |
1976-01-16 |
UIRIAMU GUROOBAA |
|
165 |
JPS5070122A - |
JP7418174 |
1974-06-28 |
JPS5070122A |
1975-06-11 |
|
|
166 |
METHOD AND APPARATUS FOR CONVEYING ARTICLES, PIECE GOODS AND/OR CONTAINERS WITHIN AT LEAST TWO CONVEYING PATH SECTIONS |
US15524364 |
2015-11-02 |
US20180229948A1 |
2018-08-16 |
Manuel KOLLMUSS; Richard ESCHLBECK |
The invention relates to a palletizing apparatus (10) and a method for conveying articles (16), piece goods, and/or bundles (18) and/or palletizable article layers, piece good layers, and/or bundle layers (20) with at least two conveyor line sections (12, 14), each in a particular conveying direction (28, 29). Each conveyor line sections include consecutive handling stations, grouping stations, and/or transfer stations (32, 33, 40, 44, 48, 50), which lead to a central loading station (24), where the article layers, piece good layers, and/or bundle layers (20) are stacked on top of each other and/or palletized in a common loading place (25). The loading station (24) is located between at least two vertically adjustable support surfaces and/or conveying surfaces (52). The common loading place (25) is supplied with article layers, piece good layers, and/or bundle layers (20). |
167 |
FEED DEVICE FOR FEEDING ROUND BLANK RINGS MADE FROM PLASTIC AND ARRANGEMENT FOR TRANSPORTING OF SUCH ROUND BLANK RINGS |
US15944856 |
2018-04-04 |
US20180222688A1 |
2018-08-09 |
HELMUT PRINZINGER |
The invention relates to an arrangement (20) to transport a round blank ring (30) made from plastic from a receiving location (35) to an assembly station (90). A every point in time, the orientation and the position of the round blank ring (30) are predefined, at least within a tolerance range. To execute a movement from top to bottom in a height direction (H), it is possible to use a feed device (34) with a motor-driven conveying unit (58). This conveying unit (58) moves one or more round blank rings (30) in a positively guided manner downward in the height direction (H) to a delivery location (36). At every point in time as this is done, the orientation of the round blank ring relative to the height direction (H) is defined, at least within a predefined tolerance range. |
168 |
Handling device for handling a rotor blade mold for producing a rotor blade of a wind turbine |
US14411824 |
2013-07-01 |
US09796116B2 |
2017-10-24 |
Arno Georgs; Herbert Biebl; Rainer Schlueter |
The present disclosure concerns a transport vehicle for handling a rotor blade mold for the production of a rotor blade of a wind power installation or a shell portion of a rotor blade of a wind power installation, adapted for use in a handling apparatus. The handling apparatus includes a first rail set for displacement of the transport vehicle in a first direction, and a second rail set for displacement of the transport vehicle in a second direction. In addition the transport vehicle includes a first wheel set including a plurality of wheels for movement on the first rail set, and a second wheel set including a plurality of wheels for movement on the second rail set. |
169 |
Palletizing device and method for handling thereof |
US14557540 |
2014-12-02 |
US09731916B2 |
2017-08-15 |
Manuel Kollmuss; Pino-Giuseppe Palumbo |
Disclosed is a palletizing device (10) with a vertically mobile transfer station (14) which is in conveying communication with upstream conveying equipment (18) for conveying items, packaged goods, packages (20), or the like, to be palletized. The transfer station (14) is followed in the conveying direction (22) by a vertically mobile loading station (16) which is in conveying communication with a stacking position (28) for palletizing the items, packaged goods, and/or packages (20). The transfer (14) and loading stations (16) which are independently adjustable in the vertical positions thereof are associated with a common support structure, having separate guide devices (30) for vertically mobile guiding and drive devices for vertical position adjustment of the transfer (14) and loading stations (16), respectively.In addition, a method for handling such a palletizing device (10) is disclosed wherein the base planes (26, 48) of the transfer (14) and loading stations (16) are approximately flush at least while a layer of items, packaged goods, and/or packages (21) is pushed over between the two stations (14, 16). |
170 |
Low Profile Transfer Conveyor for Use with Conveyor Systems |
US15143547 |
2016-04-30 |
US20170008705A1 |
2017-01-12 |
Carmen Sammauro |
The low profile transfer conveyor bridges gaps between terminal ends of contiguous multi segment conveyors and provides a driven belt bridge with a length that approximately bridges the space between the flat surfaces of conveyor belt segments of the multi segment conveyors and has a low profile which minimizes any unsupported distance across which articles must cross between conveyor belt segments by providing a small continuous section of driven conveyor belt traversing a flat surface bounded on two sides by small radius edges so the transfer conveyor edges extend almost to the flat surface of the belt segments on opposite sides of the gap that it bridges. At its ends, the belt of the transfer conveyor is driven by one or more drive pulleys. |
171 |
Dredged soils long distance transport system using magnetic field and tornado and its control method thereof |
US14388812 |
2014-05-29 |
US09517900B2 |
2016-12-13 |
Gil-Lim Yoon; YuSeung Kim |
A long distance dredged soil transport system includes a pump module including a pump for generating a compressed air and a plug flow flowing by dividing an inner state of a pipeline to a gaseous unit and a liquefied unit by introducing the generated compressed air into the pipeline by being interlinked to one lateral surface of the pipeline, a pipe module wound with a coil to apply an electromagnetic wave to the liquefied unit and including a plurality of pipelines, database stored with flow information on flow velocity and flow form in response to physical properties of liquefied unit, and a control module communicating with the pipe module, the pump module and the database and applying, to the coil, a waveform of a current matching to a flow waveform of the liquefied unit transported inside the pipeline, and a control method thereof. |
172 |
DREDGED SOILS LONG DISTANCE TRANSPORT SYSTEM USING MAGNETIC FIELD AND TORNADO AND ITS CONTROL METHOD THEREOF |
US14388812 |
2014-05-29 |
US20160325948A1 |
2016-11-10 |
Gil-Lim Yoon; YuSeung Kim |
A long distance dredged soil transport system includes a pump module including a pump for generating a compressed air and a plug flow flowing by dividing an inner state of a pipeline to a gaseous unit and a liquefied unit by introducing the generated compressed air into the pipeline by being interlinked to one lateral surface of the pipeline, a pipe module wound with a coil to apply an electromagnetic wave to the liquefied unit and including a plurality of pipelines, database stored with flow information on flow velocity and flow form in response to physical properties of liquefied unit, and a control module communicating with the pipe module, the pump module and the database and applying, to the coil, a waveform of a current matching to a flow waveform of the liquefied unit transported inside the pipeline, and a control method thereof. |
173 |
CROSS BELT SLAT SORTER |
US15213472 |
2016-07-19 |
US20160325937A1 |
2016-11-10 |
William A. Bastian, II; Garrett Clark; Eric C. Halvorson, II |
A conveyor sortation system includes a frame and two or more carriages riding along the frame in a travel direction. Each carriage includes a belt and an electric motor. The belt is oriented at a direction that is transverse to the travel direction of the carriage. The electric motor is configured to drive the belt. In one form, the belt has a width that is at most 8 inches (20.32 cm) wide. In another form, the carriages have a vertical recirculation pattern along the frame. |
174 |
Roller system for sorting produce |
US14738484 |
2015-06-12 |
US09475643B1 |
2016-10-25 |
Todd D. Odman; Delbert D. Odman |
A roller system for sorting a produce or fruit, with a conveyor having an upper run and a lower run, a roller truck with two spindles and a roller wheel between. The roller truck is attached to side-by-side conveyors each with a string of the roller trucks operating in parallel and a roller drive belt contacting the roller wheel of the roller truck on the upper run, to spin the roller wheel and the roller pair. The side-by-side roller pairs of spindles have a spindle gap between each pair and a pocket is formed between each of roller pairs for receiving the produce, such as cherries, nuts or blueberries. As the roller drive belt rotates the roller wheel, the produce is rolled and repositioned in the pocket, exposing and presenting all surfaces of the produce to an optical scanner. |
175 |
Device for turning over and conveying an object |
US14172568 |
2014-02-04 |
US09284132B2 |
2016-03-15 |
Thomas Hawighorst; Alexander Titz; Rüdiger Duwendag; Guido Tillmann |
A device for turning over an object, particularly a package of stacked sacks, having a holder device for receiving, turning over, and releasing the object, the holder device including two transport elements for conveying the object, and including at least one transport drive for the purpose of driving the transport elements, and having a rotary device for rotating the transport elements about a stationary axis of rotation, the rotary device including a rotatable frame to fasten the transport elements on both sides thereof, wherein the transport elements are fastened to the frame in a manner allowing movement, and wherein the transport drive is fastened in a torque-proof manner to the frame. |
176 |
PALLETIZING DEVICE AND METHOD FOR HANDLING THEREOF |
US14557540 |
2014-12-02 |
US20150151930A1 |
2015-06-04 |
Manuel Kollmuss; Pino-Giuseppe Palumbo |
Disclosed is a palletizing device (10) with a vertically mobile transfer station (14) which is in conveying communication with upstream conveying equipment (18) for conveying items, packaged goods, packages (20), or the like, to be palletized. The transfer station (14) is followed in the conveying direction (22) by a vertically mobile loading station (16) which is in conveying communication with a stacking position (28) for palletizing the items, packaged goods, and/or packages (20). The transfer (14) and loading stations (16) which are independently adjustable in the vertical positions thereof are associated with a common support structure, having separate guide devices (30) for vertically mobile guiding and drive devices for vertical position adjustment of the transfer (14) and loading stations (16), respectively.In addition, a method for handling such a palletizing device (10) is disclosed wherein the base planes (26, 48) of the transfer (14) and loading stations (16) are approximately flush at least while a layer of items, packaged goods, and/or packages (21) is pushed over between the two stations (14, 16). |
177 |
Diagnostic method for manufacturing processes |
US11585423 |
2006-10-23 |
US07516047B2 |
2009-04-07 |
John R. Allen |
A method for use in a system for diagnosing the causes of manufacturing defects involves process characterization. A set of forms is identified for a workpiece and for a piece of manufacturing equipment that acts upon the workpiece. The forms for the workpiece are preferably a hierarchic set of geometric forms. Each such geometric form corresponds to an aspect of the action of the manufacturing equipment upon the workpiece. A plurality of measurements is made on a defective workpiece following the hierarchical order of forms. The measurements are compared to a reference datum, and a deviation from the datum is computed. If the deviation exceeds a preselected threshold, an alert condition results, attributable to the action of the manufacturing equipment. Targeted adjustment corresponding to the action that caused the defect can then be made to the equipment. |
178 |
Automatic calculation of minimum and maximum tolerance stack |
US11243358 |
2005-10-04 |
US07477262B2 |
2009-01-13 |
Clay Tornquist; Todd Jarvinen |
Determining a minimum condition and a maximum condition of an assembly of parts includes determining a subset of the assembly of parts, constructing a tolerance chain comprised of tolerance features associated with the parts and that have tolerances that can assume maximum and minimum values, setting at least one tolerance to a minimum value or a maximum value, and calculating the minimum condition and the maximum condition of the assembly based on the setting of the tolerance. |
179 |
System and method for analyzing design tolerances |
US10059695 |
2002-01-29 |
US07103501B2 |
2006-09-05 |
Mahesh Kamatala; Robert Gardner; Debajit Guha; Hwei-Min Lu; Erik Salisbury; Raj Verma; Ashish Gandhi |
A computer program apparatus for analyzing design tolerances having a computer readable medium and computer program instructions. The computer program instructions are recorded on the computer readable medium and are executable by a processor. The computer program instructions are capable of performing the steps of facilitating the graphical identification by a user of a first and a second entity, identifying any objects related to the first and second entities, storing the identified dimensions and tolerances relating to the identified objects, and, analyzing the stored dimensions, to, in turn, determine the interfacing of the objects relative to each other. |
180 |
Automatic generation of tolerance schemes |
US11243354 |
2005-10-04 |
US20060106476A1 |
2006-05-18 |
Clay Tornquist; Todd Jarvinen; Christopher Garcia |
Automatic generation of a tolerance scheme includes accessing data defining a three-dimensional model that defines a part for manufacture, identifying a tolerance feature in the three-dimensional model, determining at least one unconstrained degree of control for the tolerance feature, automatically creating a tolerance scheme for the tolerance feature, and rendering the tolerance scheme and the three-dimensional model in a window such that the tolerance scheme annotates the tolerance feature. The tolerance scheme is based on an engineering standard for communicating a tolerance and constrains the unconstrained degree of control. |