For tightening screw connections disposed along two annular flanges to be tensioned relative to one another and forming a ring, a tool carrier movable along the ring has a tool and a sensor. It is moved along the ring at least once, wherein current longitudinal positions of the tool carrier relative to the ring are repeatedly detected as position values and the gap size between the annular flanges at the respective current position is repeatedly detected as a gap size value by the sensor. These values are transmitted to a control and evaluation unit storing gap size values conjointly with assigned position values as datasets and determining, based on the datasets, the largest or an above-average gap size value together with assigned position value as a primary position. The screw connection at the primary position or a directly adjacent one in circumferential direction is tightened by the tool.

Various embodiments include an apparatus for servicing a turbomachine, along with a related servicing method. In some cases, the apparatus includes: a system for servicing a turbomachine casing having adjacent segments joined with a set of threaded fasteners, the system including: a threaded fastener tensioning device sized to fit over ends of a threaded fastener in the set of threaded fasteners, the threaded fastener tensioning device including: a retention component for retaining a first end of the threaded fastener; and a tensioner for tensioning or de-tensioning a second end of the threaded fastener; and a mounting system coupled with the threaded fastener tensioning device, the mounting system for retaining the threaded fastener tensioning device proximate the adjacent segments of the turbomachine casing.

A screw fastening apparatus for fastening a screw member having a bearing surface with respect to a member to be fastened by rotating the screw member from a theoretical seating point to a target rotational angle, including a rotational angle sensor which senses rotational angle values of the screw member for fastening the screw member, a torque detector which detects torque values for fastening the screw member, a torque value difference detector which detects a plurality of torque value differences, each of the torque value differences is a difference of the torque values detected at intervals of a constant rotational angle, a slip detector which detects a slip of the screw member with respect to the member to be fastened, from an average of the torque value differences, and a screw fastening discontinuing unit which instructs to discontinue the screw fastening when the slip is detected by the slip detector.

The invention provides a tensioning device having a traction element and a body. The traction element includes a first lower portion of the traction element that resides in a tie-rod that is able to interlock with a threaded rod and a second upper portion of traction element that resides in a piston, the first and second portions of traction element being integral in displacement. The traction element is axially moveable in a bore of the body and co-axially mounted around the traction element, the body providing a first lower portion of the body that resides in a tubular support sleeve and a second upper portion of body that resides in a cylinder. An annular chamber is formed between the traction element and the body and intended to receive a pressurized fluid.

A locking bolt assembly (1) for securing a mantle (40) to a head assembly (60) of a crushing device includes locking bolt (10) having a head portion (10a) and a thread portion (10b); a re-useable thrust plate (30) disposed between the head portion (10a) and a top surface portion (42) of the mantle (40); one or more fasteners (20) for connecting the locking bolt (10) to the re-useable thrust plate (30); and one or more permanent jacking screws (34) for forcing the locking bolt (10) up and the thrust plate (30) down onto the top surface portion (42) of the mantle (40) so that the mantle (40) is secured on the head assembly (60).

In a method for documented tightening or retightening of a screw connection that includes a threaded bolt and a nut screwed onto the bolt and is supported on a flange surface, an exchangeable socket of a tensioning cylinder supported against the flange surface is screwed onto the free threaded end of the threaded bolt. The exchangeable socket is hydraulically tightened with longitudinal expansion of the threaded bolt while the nut is co-rotated by rotation of a rotary sleeve connected to the nut for conjoint rotation. Switching elements, in a first operating mode, allow only the exchangeable socket to be electrically driven and, in a second operating mode, allow only the rotary sleeve to be electrically driven. A process control unit provided with a documentation module is used to control the method.

A pressurising system for bolt tensioning, comprising: an inlet for receiving compressed gas; a fluid outlet for connection to a bolt tensioning device; a pump for pumping fluid for increasing the pressure at the fluid outlet, the pump being coupled to the inlet for being driven by compressed gas received at the inlet; a negative pressure generator coupled to the outlet for decreasing the pressure at the fluid outlet, the negative pressure generator being coupled to the inlet for being driven by compressed gas received at the inlet.

A stand for hosting a Multiple Stud Tensioning Machine (MSTM) for tensioning working studs, the stand comprising a first assembly designed to lie on a floor, and a second assembly designed to receive the MSTM and movable in translation with respect to the first assembly thanks to a translation system.

A hydraulic tension adaptor comprising a flange housing, a bolt support retainer, a bolt tensioning piston, a plurality of stud assemblies, and a retainer ring. The bolt tensioning piston houses a portion of the bolt support retainer. The bolt support retainer threadedly engages with the flange housing. The retainer ring threadedly engages with the bolt support retainer. Ports located on the bolt tensioning piston allow pressure to be exerted on the system via supply and bleed ports, thus applying tension to the plurality of stud assemblies simultaneously.

A hydraulic tensioner (1), comprising: abase (2); a piston (3) mounted for sliding motion relative to the base (2), the base (2) and the piston (3) defining a pressure space (4) therebetween and being arranged to be urged apart along an axis (8) upon introduction of a fluid into the pressure space (4), the tensioner (1) having an internal bore (6) along the axis (8) having first and second ends along the axis and comprising a threaded component having an internally threaded portion (7) at the first end and coupled to the piston (3); the tensioner (1) further comprising: a threaded stud (10) having an exterior thread which engages the internally threaded portion (7) of the threaded component; and a drive mechanism (12) arranged to transmit rotational motion from the second end of the internal bore (9) to the threaded stud; the tensioner being arranged such that rotational motion applied to the drive mechanism (12) at the second end causes rotation of the stud (10) relative to the threaded component, with the engagement of the exterior thread of the stud (10) and the internal thread of the threaded component causing the stud to move along the axis as it rotates.