Provided is a safety valve (10) comprising a body (12) which defines an incoming fluid passage (14) and a return fluid passage (20). The incoming fluid passage (14) generally enables a fluid to pass from a fluid reservoir (18) through the body (12) to the tool head (16). The return fluid passage (20) generally enables a fluid to return from the tool head (16) through the body back to the fluid reservoir (18). The body (12) further comprises a diverter (22) which is displaceable between an active position and an inactive position. When the diverter (22) is in the active position, the diverter (22) redirects the fluid via a shunting passage (24) from the incoming fluid passage (14) to the return passage (20) to prevent operation of the tool head (16).

Provided is a safety valve (10) comprising a body (12) which defines an incoming fluid passage (14) and a return fluid passage (20). The incoming fluid passage (14) generally enables a fluid to pass from a fluid reservoir (18) through the body (12) to the tool head (16). The return fluid passage (20) generally enables a fluid to return from the tool head (16) through the body back to the fluid reservoir (18). The body (12) further comprises a diverter (22) which is displaceable between an active position and an inactive position. When the diverter (22) is in the active position, the diverter (22) redirects the fluid via a shunting passage (24) from the incoming fluid passage (14) to the return passage (20) to prevent operation of the tool head (16).

Apparatus and associated methods relate to dual safety touch button systems for generating machine operation commands, according to predetermined safety guidelines, from status information received via an intercommunications link (ICL) operably connecting the dual safety touch buttons (STBs). In an illustrative example, each of a pair of STBs includes a processor configured to receive, via an intercommunications link port, status information from the other STB. In response to the received information and predetermined safety guidelines, the STBs may generate machine operation commands that operate a pair of relay switches. In some embodiments, each STB may be activated within a substantially simultaneous period (e.g., less than 0.5 seconds) to actuate corresponding relay switches for operating a potentially dangerous machine.

Production and work machines are to be able to be more safely operated. Thereto, they can be equipped with a safety device, which comprises a light curtain, a first and a second reflection device, which are each formed for reflecting light of the light curtain, and a first identification element integrated in the first reflection device as well as a second identification element integrated in the second reflection device. Moreover, the safety device comprises a first sensor device and a second sensor device for reading out the identification elements. A control device provides a start signal for the machine only if the first sensor device reads out the first identification information and the second sensor device reads out the second identification information at the same time.

An equipment locking and de-energization management system (7) is configured to guarantee safety during the locking and de-energization of a power source (6) of an item of equipment (7) during maintenance thereof. The system includes an intelligent lock (1) to be inserted into the power source (6) and perform the locking thereof, a control device (2) configured to manage and sort the locking steps and a central server (15) to assist with the communication between the elements of the locking and de-energization management system. Also described is an equipment locking and de-energization management method (7) which makes use of the locking and de-energization management system, enhancing the safety, efficiency and productivity during locking and de-energization of the power source (6) of an item of equipment (7) undergoing maintenance.

An equipment locking and de-energization management system (7) is configured to guarantee safety during the locking and de-energization of a power source (6) of an item of equipment (7) during maintenance thereof. The system includes an intelligent lock (1) to be inserted into the power source (6) and perform the locking thereof, a control device (2) configured to manage and sort the locking steps and a central server (15) to assist with the communication between the elements of the locking and de-energization management system. Also described is an equipment locking and de-energization management method (7) which makes use of the locking and de-energization management system, enhancing the safety, efficiency and productivity during locking and de-energization of the power source (6) of an item of equipment (7) undergoing maintenance.

An equipment locking and de-energization management system (7) is configured to guarantee safety during the locking and de-energization of a power source (6) of an item of equipment (7) during maintenance thereof. The system includes an intelligent lock (1) to be inserted into the power source (6) and perform the locking thereof, a control device (2) configured to manage and sort the locking steps and a central server (15) to assist with the communication between the elements of the locking and de-energization management system. Also described is an equipment locking and de-energization management method (7) which makes use of the locking and de-energization management system, enhancing the safety, efficiency and productivity during locking and de-energization of the power source (6) of an item of equipment (7) undergoing maintenance.

An equipment locking and de-energization management system (7) is configured to guarantee safety during the locking and de-energization of a power source (6) of an item of equipment (7) during maintenance thereof. The system includes an intelligent lock (1) to be inserted into the power source (6) and perform the locking thereof, a control device (2) configured to manage and sort the locking steps and a central server (15) to assist with the communication between the elements of the locking and de-energization management system. Also described is an equipment locking and de-energization management method (7) which makes use of the locking and de-energization management system, enhancing the safety, efficiency and productivity during locking and de-energization of the power source (6) of an item of equipment (7) undergoing maintenance.

The disclosure is based on a hand-held power tool having at least one switch device which comprises at least one switching element at least for activating a power supply of a drive unit, having at least one quick-change tool holder which is provided for holding an insertion tool which is different from an insertion tool with an SDS® shaft having a maximum transverse extent of 10 mm and/or having at least one accumulator interface. It is proposed that the at least one switching device comprises at least one locking unit which is provided for maintaining, at least essentially independently of an effect of an operator activation force, an active operating mode which can be activated by actuating the at least one switching element.

The disclosure is based on a hand-held power tool having at least one switch device which comprises at least one switching element at least for activating a power supply of a drive unit, having at least one quick-change tool holder which is provided for holding an insertion tool which is different from an insertion tool with an SDS® shaft having a maximum transverse extent of 10 mm and/or having at least one accumulator interface. It is proposed that the at least one switching device comprises at least one locking unit which is provided for maintaining, at least essentially independently of an effect of an operator activation force, an active operating mode which can be activated by actuating the at least one switching element.