A cup is in a bottomed tubular shape to receive an injector along an injector axis. A bracket is extended from a sidewall of the cup. The bracket includes at least one arm and a body. The at least one arm connects the body with the cup. The body forms a screw opening configured to receive a screw along a screw axis. The body has a pivot end on an opposite side of the screw axis from the injector axis.

The present disclosure relates to a fuel rail assembly for an internal combustion engine. In some embodiments, a fuel rail assembly for an internal combustion engine may include an elongated tubular fuel rail and a plurality of fuel delivery lines branching off from the fuel rail for hydraulically coupling the fuel rail to fuel injectors operable to inject fuel into the combustion engine. Also, an injector cup for receiving a fuel inlet portion of a respective one of the fuel injectors, a pipe arranged between the fuel rail and the injector cup for hydraulically coupling the injector cup to the fuel rail, and a fixation bracket configured for positionally fixing the fuel delivery line with respect to the engine. The injector cup, the pipe, and the fixation bracket are individual parts. A rigid connection is established between the fixation bracket and a portion of the pipe, said portion spaced apart from each of the fuel rail and from the injector cup. The fixation bracket is a one-pieced part which adjoins the pipe and is spaced apart from the injector cup and the fuel rail.

Disclosed herein is the structure of a GDI fuel delivery pipe. The structure of a GDI fuel delivery pipe includes: a main pipe configured to flow fuel through a hollow formed therein; a plurality of injector cups formed in cylindrical shapes having open lower ends, and configured to be coupled and fastened to the main pipe, to flow fuel therethrough, and to be coupled to respective injectors; a plurality of mount holders configured to form tubular parts each having a bolt hole in a lengthwise direction, and to be coupled and fastened to the main pipe; and fastening members configured to fasten the plurality of injector cups or mount holders to the main pipe by being coupled to the outer circumferential surface of the main pipe at both left and right ends thereof while surrounding the outer circumferences of the plurality of injector cups or mount holders.

A forged fuel rail for a motor vehicle includes a tubular base body, an inlet formed in one piece on the base body and made of a same material as the base body. Further formed in one piece on the base body and made of a same material as the base body are a plurality of injector mounts and, a support element for securement of the fuel rail to a further motor vehicle component. A reinforcement member extends between a corresponding one of the injector mounts and the support element and is formed in one piece on the base body and made of a same material as the base body. The reinforcement member is hereby formed from a flash created during a forging process.

A fuel rail assembly for a combustion engine includes a fuel rail, a plurality of fuel injector cups arranged and configured to face a cylinder head of a combustion engine and being hydraulically and mechanically coupled to the fuel rail directly or via pipe elements, and at least one support element configured to be fixedly coupled to the cylinder head. The at least one support element is fixedly coupled to two of the injector cups or to two of the pipe elements being coupled to the injector cups.

In some examples, a clip prevents relative rotation between a fuel injector and an injector cup of a fuel rail. For instance, the fuel injector may be rotated following insertion into the injector cup to prevent removal of the fuel injector. The clip includes a clip body having a pair of arms extending from the clip body with an opening between the arms for receiving the fuel injector. A tab extends from the clip body into the opening for engaging a first alignment slot in the injector cup and a second alignment slot in the fuel injector when the clip is installed on the fuel injector. Following installation of the clip on the fuel injector, the tab is disposed in the first and second alignment slots to prevent relative rotation between the fuel injector and the injector cup.

A bearing bush is for a holder, which is for fastening a component, particularly of a fuel distributor, to an add-on structure. The bearing bush has an inner bush part, which is made of a metallic material, and an outer bush part, which is made of a metallic material, and an elastically deformable damping element. The outer bush part has a continuous recess, in which the inner bush part is situated. The damping element is situated between the inner bush part and the outer bush part. A holder having such a bearing bush is also specified. In addition, a fuel-injection system having a fuel distributor and at least one holder is specified, which is used for fastening the fuel distributor on an internal combustion engine.

A fuel injector for an internal combustion engine is disclosed. The fuel injector is installable in a cylinder head bore of a cylinder head of the engine and has a body region arranged to be received within the cylinder head bore, and a head region arranged to extend outside the cylinder head bore to protrude from the cylinder head when the injector is installed in the cylinder head bore. The injector includes a first valve needle arranged to control the injection of a gaseous fuel from a first outlet, a second valve needle arranged to control the injection of a liquid fuel from a second outlet, a gaseous fuel inlet for admitting the gaseous fuel to the injector, and a liquid fuel inlet port for admitting the liquid fuel to the injector. The gaseous fuel inlet is disposed in the body region of the injector, and the liquid fuel inlet port is disposed in the head region of the injector. The injector can also include an internal accumulator volume so that an external fuel rail is not necessary.

A fuel injector clamp has a clamp body extending between a fuel rail side and a cylinder head side. The fuel rail side has a bolt fixing surface extending in a first plane and a rail mounting surface extending in an oblique second plane relative to the first plane. The cylinder head side has a clamp mounting surface extending in a third plane parallel to the first plane. The clamp body defines a first bolt bore, a second bolt bore, and an injector pocket. The first bolt bore extends from the bolt fixing surface at the fuel rail side through the clamp body to the cylinder head side perpendicular to the bolt fixing surface and the clamp mounting surface. The second bolt bore extends from the rail mounting surface at the fuel rail side into the clamp body perpendicular to the rail mounting surface. The injector pocket extends through the clamp mounting surface perpendicularly through the clamp body to the rail mounting surface. The first bolt bore and the injector pocket extend along parallel axes, and the second bolt bore extends along an axis that is oblique to the parallel axes.

A boot in a boot assembly in a fuel system includes an elongate boot body defining a longitudinal axis and having an inner boot surface. An injector portion of the boot has a window formed therein receiving an electrical connector of a fuel injector. The injector portion also includes a plurality of radially inward standoff protrusions in contact with the fuel injector to maintain an air gap clearance between an inner surface of the boot and the fuel injector.