A stub of a via formed in a printed circuit board is backdrilled to a predetermined depth. A capacitance probe is positioned within the via. Then the capacitance probe is used to obtain a test capacitance measurement. The test capacitance measurement is compared to a predetermined baseline capacitance measurement. Residual conductive plating material in the backdrilled stub causes the test capacitance measurement to exceed the predetermined baseline capacitance measurement. An indication is made that the predetermined baseline capacitance measurement has been exceeded.

The present disclosure is directed toward a machine tool configured to perform small-scale, high-accuracy drilling operations for small-hole applications. The small-hole applications for which the machine tool is designed includes holes with one or more diameters. A part may have a larger-diameter hole that penetrates through a fraction of the thickness of a part and a smaller-diameter hole that penetrates from the bottom of the larger-diameter hole through the remainder of the part thickness. Additionally, the machine tool may be used with parts in any of the following categories: (i) both the step-hole and the flow-hole are created using the machine tool; or, (ii) the step-hole is created with an up-stream process and the machine tool may accept the part, measure the step-holes and create the flow-holes; or, (iii) no step-hole is used and the machine tool may accept the part, measure the raw surface and create the flow-holes.

The invention relates to a deflector attachment (1), which is designed to be arranged on a predetermined drilling tool (111) having a predetermined drilling needle (19) which can be supported and guided along a drill axis (b) and which protrudes out of a housing (12) of the drilling tool (111) at the front. The deflector attachment (1) can be arranged on the front face of the drilling tool (111) and has a deflecting housing in which, in an arrangement for use, the drilling needle (19) emerging from the housing (12) of the drilling tool (111) can be guided. In the arrangement for use the deflecting housing is curved by a predetermined angle (a) and provides a drilling needle exit axis (a) which is offset by the predetermined angle (a) in relation to the predetermined drill axis (b) of the drilling tool (111). The invention further relates to a drilling device having a deflector attachment according to the invention, to a conversion set for drilling devices, and to a method for carrying out drilling or drill resistance measurements at a predetermined location of an object using the drilling device with deflector attachment.

A powered high-speed cutting tool that also locates objects behind sheet material and subsequently cuts around the object. The tool incorporates at least one sensor having a transceiver emitting a signal to detect at least one from the group of object density, conductivity, distance, and identification. The sensor is housed within a sensor unit that is part of the body of the cutting tool. The sensor unit can be incorporated into the body or removable from the cutting tool. A marking unit is used to mark the cutting area of the sheet material and is generally part of or located near a sensor unit. Indicator members, such as lights, audio, and/or display screen, are used to provide information to the user.

The invention relates to a deflector attachment (1), which is designed to be arranged on a predetermined drilling tool (111) having a predetermined drilling needle (19) which can be supported and guided along a drill axis (b) and which protrudes out of a housing (12) of the drilling tool (111) at the front. The deflector attachment (1) can be arranged on the front face of the drilling tool (111) and has a deflecting housing in which, in an arrangement for use, the drilling needle (19) emerging from the housing (12) of the drilling tool (111) can be guided. In the arrangement for use the deflecting housing is curved by a predetermined angle (a) and provides a drilling needle exit axis (a) which is offset by the predetermined angle (a) in relation to the predetermined drill axis (b) of the drilling tool (111). The invention further relates to a drilling device having a deflector attachment according to the invention, to a conversion set for drilling devices, and to a method for carrying out drilling or drill resistance measurements at a predetermined location of an object using the drilling device with deflector attachment.

A powered high-speed cutting tool that also locates objects behind sheet material and subsequently cuts around the object. The tool incorporates at least one sensor having a transceiver emitting a signal to detect at least one from the group of object density, conductivity, distance, and identification. The sensor is housed within a sensor unit that is part of the body of the cutting tool. The sensor unit can be incorporated into the body or removable from the cutting tool. A marking unit is used to mark the cutting area of the sheet material and is generally part of or located near a sensor unit. Indicator members, such as lights, audio, and/or display screen, are used to provide information to the user.

Certain embodiments of the disclosure may include systems, methods, and apparatus for locating and drilling closed holes of a gas turbine component. According to an example embodiment, the method can include receiving position data associated with one or more holes in a gas turbine component; receiving predefined hole position data from manufacturing data associated with the gas turbine component; determining at least one missing hole, based at least in part on comparing the received position data to the predefined hole position data; and drilling at least one hole in the gas turbine component corresponding to the determined at least one missing hole.

A drilling system includes a drilling machine, configured to drill a hole in a work piece along a drilling axis, a deployment mechanism, attached to the drilling machine, a measuring probe, attached to the deployment mechanism, and a controller, coupled to the drilling machine, the measuring probe, and the deployment mechanism. The measuring probe is configured to produce a signal indicative of an actual geometric parameter of the hole when inserted therein. The deployment mechanism is configured to selectively align the measuring probe along the drilling axis. The controller is configured to cause insertion of the measuring probe into the hole, and to receive the signal from the measuring probe.

A powered high-speed cutting tool that also locates objects behind sheet material and subsequently cuts around the object. The tool incorporates at least one sensor having a transceiver emitting a signal to detect at least one from the group of object density, conductivity, distance, and identification. The sensor is housed within a sensor unit that is part of the body of the cutting tool. The sensor unit can be incorporated into the body or removable from the cutting tool. A marking unit is used to mark the cutting area of the sheet material and is generally part of or located near a sensor unit. Indicator members, such as lights, audio, and/or display screen, are used to provide information to the user.

Disclosed is a technique of achieving weight reduction of a forged rotary body while improving productivity of the forged rotary body. Temporary center holes are set for each of two or more samples extracted from one forging lot of a plurality of forged rotary bodies produced within a time period after a die misalignment adjustment through before a next die misalignment adjustment. Then, a virtual final shape of each of the samples is simulated on an assumption that machining is performed on the basis of the temporary center holes, and a rotational imbalance amount is calculated. Then, an average value of the rotational imbalance amounts in all of the samples in the same forging lot is calculated, and center-hole positions which allow the average value to become zero are set as center hole machining positions for all of the forged rotary bodies in a corresponding forging lot.