61 |
Device and Method for Setting a Press-In Element |
US14930825 |
2015-11-03 |
US20160052198A1 |
2016-02-25 |
Fabian FISCHER; Oguzhan EROGLU |
A device and a method are provided for setting a press-in element into a workpiece at a predetermined location. The device includes main body; a fixing unit, which is attached to the main body and which is designed to fix the workpiece; and a processing unit, which is attached to the main body and includes: a boring unit, which is designed to create a bore in the workpiece fixed by the fixing unit; and a pressing unit, which is designed to press a press-in element into the bore. The method fixes the workpiece; creates a bore in the workpiece; positions a press-in element over the bore; and presses the press-in element into the bore, wherein a single device is used to carry out the method. |
62 |
FIBER REINFORCED PLASTIC BOLT AND METHOD FOR PRODUCING THE SAME |
US13955317 |
2013-07-31 |
US20130315689A1 |
2013-11-28 |
Hoon-Heui JEONG; Yong-Min PARK; Hyun-Seok KIM |
A fiber reinforced plastic bolt (FRP) and a method for producing the same are disclosed. The FRP bolt is useful in the industrial areas which require a bolt having electric-insulation, anti-corrosive, thermal-insulation, and non-magnetic properties. The method for producing the FRP bolt includes the steps of: winding a prepreg around a surface of an internal body, wherein the internal body includes a first reinforcing fiber which is unidirectionally aligned along the axis of the bolt, and a synthetic resin which is impregnated into the first reinforcing fiber, and the prepreg includes a second reinforcing fiber and a thermosetting resin which is impregnated into the second reinforcing fiber; forming a fiber reinforced plastic round bar by heat-hardening the prepreg; and forming a screw thread on the surface of the fiber reinforced plastic round bar. |
63 |
FIBER REINFORCED PLASTIC BOLT AND METHOD FOR PRODUCING THE SAME |
US13321414 |
2010-06-03 |
US20120063866A1 |
2012-03-15 |
Hoon-Heui Jeong; Yong-Min Park; Hyun-Seok Kim |
A fiber reinforced plastic bolt(FRP) and a method for producing the same are disclosed. The FRP bolt is useful in the industrial areas which require a bolt having electric-insulation, anti-corrosive, thermal-insulation, and non-magnetic properties. The method for producing the FRP bolt includes the steps of: winding a prepreg around a surface of an internal body, wherein the internal body includes a first reinforcing fiber which is unidirectionally aligned along the axis of the bolt, and a synthetic resin which is impregnated into the first reinforcing fiber, and the prepreg includes a second reinforcing fiber and a thermosetting resin which is impregnated into the second reinforcing fiber; forming a fiber reinforced plastic round bar by heat-hardening the prepreg; and forming a screw thread on the surface of the fiber reinforced plastic round bar. |
64 |
METHOD FOR PRODUCING A MOULDED PART WITH AN ANNULAR CROSS-SECTION AND MOULDED PART PRODUCED ACCORDING TO A METHOD OF THIS TYPE |
US12937308 |
2009-04-09 |
US20110150602A1 |
2011-06-23 |
Günter Sieper; Peik-Christian Witte |
A molded part and a method for producing the molded part. The molded part is rotationally symmetrical or at least partially annular in cross section and formed by a plasticized polymeric mass containing fibers being injected through an injection opening into a cavity of a molding tool. Once the polymeric mass has solidified, the molded part is removed from the tool. Injection into the cavity takes place through at least two injection openings in such a way that the fibers are aligned predominantly in the main stress directions of axial tension and torsion in the molded part. |
65 |
Product having ultra high molecular weight plastic parts |
US10287228 |
2002-11-04 |
US06676351B1 |
2004-01-13 |
Steven A. Bruns |
A method of making a UHMWPE body combined with a bolt, a cap screw, a reinforcing member uses a compression molding machine equipped with a male and female mold set. Particulate UHMWPE dispensed into the cavity of the female mold surrounds the head of the bolt and screw and reinforcing member. Pressure and heat applied to the particulate UHMWPE molecularly bonds the UHMWPE to the bolt, screw, and reinforcing member. |
66 |
Method for making product and product having ultra high molecular weight plastic parts |
US09535691 |
2000-03-27 |
US06475094B1 |
2002-11-05 |
Mark W. Bruns; Steven A. Bruns |
A method of making a UHMWPE body combined with a bolt, a cap screw, a reinforcing member uses a compression molding machine equipped with a male and female mold set. Particulate UHMWPE dispensed into the cavity of the female mold surrounds the head of the bolt and screw and reinforcing member. Pressure and heat applied to the particulate UHMWPE molecularly bonds the UHMWPE to the bolt, screw, and reinforcing member. |
67 |
Manufacturing method for U-bolts |
US163473 |
1998-09-30 |
US6113826A |
2000-09-05 |
Isao Tajima; Yuji Kometani |
A manufacturing method for U-bolts comprising the steps of (a) winding a linear, tape or cloth member made of fiber reinforced plastics in which at least a part of the fiber is oriented in three-dimensional directions around a mandrel having a substantially oval or rectangular section (b) making a pipe molded article by hardening the linear, tape or cloth member wound around the mandrel, (c) cutting the hardened pipe molded article into slices transverse to a longitudinal axis of the mandrel, (d) separating the molded article cut into slices into at least two U-shaped portions, and (e) forming screw portions at tip portions of a pair of separated U-shaped portions. |
68 |
Method for coating adhesive surfaces of fastening elements with hot-melt
adhesives |
US297466 |
1998-04-28 |
US6083558A |
2000-07-04 |
Michel Bremont |
A process for coating a fastening member with a hot melt adhesive. The process includes applying adhesive in a solid form such as powder, pellet or a compressed plate of adhesive onto the surface of the fastening member, pressing the adhesive against the adhesive bearing surface of the fastening member, and then heating the adhesive, while it is subjected to pressure, to a temperature high enough to melt the adhesive. In the preferred embodiment heating is accomplished by induction. The fastening members may be preheated to a temperature in the range of 50.degree.-90.degree. to increase the speed of the process. |
69 |
Method of transfer molding fiber-reinforced resin bolt products |
US481128 |
1990-02-20 |
US5057257A |
1991-10-15 |
Mark K. Neitzke |
A method of molding fiber-reinforced bolts including wrapping a bundle of unidirectional fibers axially around a core, placing the core in a molding cavity, supplying fiber-reinforced resin to the mold cavity, and curing the resin encapsulated core. The core of the bolt product can also be made of a fiber-reinforced composite resin material. |
70 |
Patch-type self-locking screw fasteners |
US268578 |
1988-11-08 |
US4927307A |
1990-05-22 |
Walter P. Fitzgerald; Beatrix Y. Sanders; Mansour A. H. Bagheri |
Thermoplastic polymer locking elements are formed on threaded fasteners to provide a range of self-locking torque characteristics. The thermoplastic resins are of the type that crystallize during cooling from the molten state.The crystallizable polymers are preferably applied in film form to preheated threaded fasteners. By correlation of the preheat temperature, the length of time during which the molten polymer is allowed to melt and flow onto the thread surfaces, and the rate of cooling of the assembly, the geometry of the locking element and the degree of crystallinity of the polymer are controlled. |
71 |
Composite fastener |
US133550 |
1987-12-16 |
US4909690A |
1990-03-20 |
Roland H. Gapp; Clyde Simmons |
A threaded fastener is made of a composite material made of layers extending parallel to the fastener axis and having elongated filament fibers. A portion of the fibers extend parallel to the axis of the fastener to provide tensile and shear strength to the fastener, and a portion of the fibers extend parallel to the load-bearing thread faces to enhance tensile strength to the threads. |
72 |
Pin for connecting machine elements with each other |
US600868 |
1984-04-16 |
US4505979A |
1985-03-19 |
Christoph Ruegg; Peter Voirol |
In order to provide a pin for connecting machine parts with one another, which is of optimally light weight, the pin is of a compound structure comprising a core of filler-reinforced synthetic plastics resin and a metallic envelope. As filler there are used quartz sand or carbon fibers. The envelope is preferably seated on the core under circumferential tensile bias. The manufacture of the pin takes place, for instance, by pressing the filler and a matrix resin system directly into a suitably prepared envelope. |
73 |
Pin for connecting machine elements with each other |
US479343 |
1983-03-28 |
US4456653A |
1984-06-26 |
Christoph Ruegg; Peter Voirol |
In order to provide a pin for connecting machine parts with one another, which is of optimally light weight, the pin is of a compound structure comprising a core of filler-reinforced synthetic plastics resin and a metallic envelope. As filler there are used quartz sand or carbon fibers. The envelope is preferably seated on the core under circumferential tensile bias. The manufacture of the pin takes place, for instance, by pressing the filler and a matrix resin system directly into a suitably prepared envelope. |
74 |
Method of securing an adhesive attachment assembly to a substrate |
US188963 |
1980-09-19 |
US4338151A |
1982-07-06 |
Charles G. Hutter, III |
A method and apparatus making use of that method for applying pressure to an element to be adhesively or comparably secured to a substrate. An example of such an apparatus is found in an adhesive patch and means for applying the patch to a surface which may have been ruptured. |
75 |
Induction heating fixture for applying adhesive-backed articles |
US837059 |
1977-09-28 |
US4128449A |
1978-12-05 |
Robert G. Kobetsky |
A fixture for accurately applying discrete adhesive-backed articles to a support surface through the use of induction heat. Aligning and positioning means are associated with the faces of U-shaped cores to keep the end faces of the core in abutting relationship with the article being heated but permit the article and core combination to move slightly in compound direction to accommodate support surface variations or curvature. |
76 |
樹脂溶着構造体とその製造方法 |
JP2014215374 |
2014-10-22 |
JP6379992B2 |
2018-08-29 |
波多野 大督; 江川 貴久 |
|
77 |
Apparatus for bonding by placing the retaining element to the support surface |
JP2001551155 |
2000-12-19 |
JP3604664B2 |
2004-12-22 |
シュラー オリヴィエ; ブルモン ミシェル; レルー ヤニック |
The present invention is used for setting and bonding fasteners to support surfaces. The fasteners are provided with connecting surfaces which are coated with a dry hot-melt-type adhesive on the bare side thereof. The adhesive can be reactivated by means of heat treatment. The setting device includes a housing ( 1 ) having a receiving component ( 2 ) that is displaceably guided therein and is used for the fastener ( 3 ) as well as means for quickly heating the hot-melt-type adhesive, lowering the receiving component ( 2 ) and pressing the adherent ( 25 ) after the adhesive has been melt on. Heating is carried out by means of hot air (H) which is supplied passing the housing ( 1 ) and in that the receiving component ( 2 ) is surrounded by a closed wall ( 7 ) that extends from the hot air discharge location in the housing ( 1 ) to the fastener ( 3 ). The hot air (H) can thus be conveyed to the adhering hot-melt-type adhesive before or while the fastener ( 3 ) rests on the support surface ( 25 ). |
78 |
Apparatus for bonding by placing the retaining element to the support surface |
JP2001551155 |
2000-12-19 |
JP2003519714A |
2003-06-24 |
シュラー オリヴィエ; ブルモン ミシェル; レルー ヤニック |
The present invention is used for setting and bonding fasteners to support surfaces. The fasteners are provided with connecting surfaces which are coated with a dry hot-melt-type adhesive on the bare side thereof. The adhesive can be reactivated by means of heat treatment. The setting device includes a housing ( 1 ) having a receiving component ( 2 ) that is displaceably guided therein and is used for the fastener ( 3 ) as well as means for quickly heating the hot-melt-type adhesive, lowering the receiving component ( 2 ) and pressing the adherent ( 25 ) after the adhesive has been melt on. Heating is carried out by means of hot air (H) which is supplied passing the housing ( 1 ) and in that the receiving component ( 2 ) is surrounded by a closed wall ( 7 ) that extends from the hot air discharge location in the housing ( 1 ) to the fastener ( 3 ). The hot air (H) can thus be conveyed to the adhering hot-melt-type adhesive before or while the fastener ( 3 ) rests on the support surface ( 25 ). |
79 |
Spin-welded assembly |
JP2001166444 |
2001-06-01 |
JP2002028976A |
2002-01-29 |
GOSS DAVID C |
PROBLEM TO BE SOLVED: To provide a spin-welded assembly into which a fixture which is engaged with a plastic work piece is inserted without generating a defect on the decorative surface of the work piece or deteriorating it and which holds the fixture. SOLUTION: The spin-welded assembly has (a) a spin-welded assembly 128 having at least one wall 134 and (b) a plastic insert 122 having a hole 146 in its inside. The wall provides an opening 136 in its inside, and the opening provides a boss 124 protruding outward or a cavity denting inward. The insert inserted into the opening of the wall gives engagement/contact between the outer surface 180 of the insert and the inner surface 178 of the wall. |
80 |
The method for coating the adhesive surface of the fixing element in the hot-melt type adhesive |
JP51996998 |
1997-10-07 |
JP2001511059A |
2001-08-07 |
ブルモン ミシェル |
PCT No. PCT/EP97/05501 Sec. 371 Date Apr. 28, 1999 Sec. 102(e) Date Apr. 28, 1999 PCT Filed Oct. 7, 1997 PCT Pub. No. WO98/18612 PCT Pub. Date May 7, 1998A process for coating a fastening member with a hot melt adhesive. The process includes applying adhesive in a solid form such as powder, pellet or a compressed plate of adhesive onto the surface of the fastening member, pressing the adhesive against the adhesive bearing surface of the fastening member, and then heating the adhesive, while it is subjected to pressure, to a temperature high enough to melt the adhesive. In the preferred embodiment heating is accomplished by induction. The fastening members may be preheated to a temperature in the range of 50 DEG -90 DEG to increase the speed of the process. |