Abstract: The invention relates to a device for optically measuring distance, in particular a hand-held device, comprising an transmitter unit (12) which is provided with a light source (17, 18) for transmitting optical measuring radiation (13, 20, 22) to a target object (15), and a capturing unit (14) which is arranged at a distance on the optical axis (38) of the transmitter unit (14). Said capturing unit (14) comprises at least one optical detector (54) comprising a detection surface (66) for capturing optical radiation (16, 49, 50) reflected by the target object (15). According to the invention, the detection surface (66) of the detector (54) comprises an optical near range element (68), whose optically active surface (72, 74) is elongated in the direction (61) of the radiation shift for receding target object separations (48) and expands or has at least one essentially constant extension.

Abstract: The invention relates to an electro-optical measuring device, in particular a hand-held device (10) for contactless distance measurement, comprising an optical transmission path (28), which has a first optical axis (72) and which has at least one optical transmitter (20) for emitting a measurement signal, and also comprising a reception path (29) having a second optical axis (74), which is spaced apart from the first optical axis (72), with at least one reception optic (32) for focusing a measurement signal in the direction of a receiver (26), and also comprising an optical near range element (60) for parallax compensation. It is proposed that the near range element (60) be embodied rotationally symmetrically with respect to the second optical axis (74).

Abstract: The invention is based on a measuring device, in particular a distance measuring device, having a transmission unit (18) for transmitting a measurement signal (22) and a processing unit (30) which is intended to process the measurement signal (22) and has a frequency response (70) having a first resonant frequency range (76) in which the measurement signal (22) is arranged. The invention proposes that the frequency response (70) has at least one second resonant frequency range (78) in which the measurement signal (22) is arranged during a measurement.

Abstract: An electro-optical measuring device, in particular a hand-held device for contactless distance measurement, has an optical transmission path that includes at least one optical transmitter for transmitting a measurement signal, a reception path with at least one receiving optics for bundling a measurement signal in the direction of a receiver, and an optics carrier, which accommodates components of the transmission and reception path and the is made of plastic.

Abstract: The invention relates to a distance measuring unit (10) for contactless distance measurement, in particular a handheld unit, with a housing (12, 40), which has a housing front side (14), which points in the measurement direction (32), and a housing rear side (16), which faces away therefrom, wherein the housing rear side (16) forms a first reference plane (AA) for the distance measurement, and with at least one measurement stop (5) of a measurement stop element (4), which can be moved out of the housing (12). The invention proposes that the measurement stop element (46) is mounted in the housing (12, 40) in such a way that it moves automatically out of the housing (12, 40) once a locking apparatus (62, 63, 65) has been released and is optionally moved at least into a first (1) or into a second (1) measurement position.

Abstract: In a method for detecting objects enclosed in a medium, a measurement signal correlated with an enclosed object is measured and used to generate a second signal, which reflects the measured signal strength of the measurement signal in a segmented manner by associating intervals of the signal strength of the measurement signal with individual segment units of the second signal, and the threshold values of the individual segment units of the second signal are varied depending on the measured signal strength of the measurement signal.

Abstract: A sensor for locating metallic objects, in particular a metal sensor for building materials, includes at least one transmission coil and at least one reception conductor loop system that are inductively coupled to one another. The reception conductor loop system is made up of conductor structures on a printed circuit board. A second reception conductor loop system can be provided, which is situated coaxial to the first reception conductor loop system in a common first plane with it on the printed circuit board. The sensor preferably operates in a frequency range between 1 kHz and 10 kHz.

Abstract: A device for optically measuring distance, in particular a hand-held device, comprising an transmission unit (12) which is provided with a light source (17, 18) for emitting optical measuring radiation (13, 20, 22) towards a target object (15), and a capturing unit (14) which is arranged at a distance from the optical axis (38) of the transmission unit (12). The capturing unit (14) comprises at least one optical detector (54) for capturing optical radiation (16, 49, 50) reflected by the target object (15). The detector (54) of the capturing unit (14) comprises a plurality of light-sensitive surfaces (70, 72, 74; 170, 172, 174; 270, 272, 274; 370, 372; 470, 472; 570, 572) which are separated from each other and which are be activated separately. The invention also relates to a method for operating a device for optically measuring distance.

Abstract: The invention relates to a method for measurement of a line (S), in particular, an optical distance measurement method, whereby an input means (24,42) of a distance measuring device (20,22) is operated, which triggers a measuring sequence of distance measurements, during which individual measurements (10-16) of distances from the distance measuring device (20,22) triggered by the distance measuring device (20,22) are carried out perpendicular to the line (s) for measurement. According to the invention, at least one maximum value (10,16) and at least one minimum value of the distances are determined from the measuring sequence and the length of the line (s) determined from the at least one maximum value (10,16) and the at least one minimum value (13). The invention further relates to a distance measuring device (20,22), in particular, a hand-held measuring device for carrying out said method.

Abstract: The invention relates to a method for mounting and alignment of an electro-optical apparatus, in which an optic (42) is oriented in three axes (X;Y;Z) relative to a further component (26, 46), in particular a method for alignment of a receiving optic (42) relative to an optical receiver (46). The invention proposes that the optic (42) is first aligned in a first (X) and a second direction (Y) and the optic (42) is subsequently fixed to an optical carrier (40) in the third direction (Z) by means of a welding process. The invention furthermore relates to a measuring device, in particular a distance measuring device (10), aligned according to the method of the invention.

Abstract: The invention relates to a distance measuring device with a control interface. According to the invention, the control interface has at least one contact-sensitive entry unit.

Abstract: The invention relates to a method for detecting objects (12) that are enclosed in a medium (10). According to said method, a test signal (18) that makes it possible to obtain information about the position of the enclosed object (12) is generated via at least one transmission coil (14) and at least one receiving conductor loop system (16) which are inductively coupled to each other. The frequency (fM) of the test signal (UM) is modified in accordance with the signal intensity of the detected test signal (18). The invention further relates to a measuring apparatus, especially a hand-held locating device (24, 124), for carrying out the disclosed method.

Abstract: A detector for locating metallic objects includes a transmit coil (116, 216) and at least two receive coils (112, 114; 212, 214), which are inductively coupled to one another; the at least two receive coils (112, 114; 212, 214) are located coaxial to one another in a plane (126, 226), and the transmit coil (116, 216) is located in a parallel plane with a height offset. Additional compensating windings (130, 132; 230, 232) of at least one of the receive coils (112, 114; 212, 214) are formed adjacent to a transmit coil (116, 216).

Abstract: A method for locating objects enclosed in a medium, comprising the steps of generating a measurement signal correlated with an enclosed object; using the generated measurement signal to produce a signal which represents a difference between at least a first state which is “object detected” and at least a second state which is “no object detected”; switching from the first state “object detected” to the second state “no object detected” if a magnitude of the measurement signal being measured currently falls below a previously measured local maximum value of the measurement signal by a predefined first percentage.

Abstract: The invention relates to a measuring instrument, particularly a hand-held instrument (10) for measuring distances, comprising at least one transmission branch (28) for a test signal and adjustable switching means (36) for deflecting the test signal. The switching means (36) reflect at least a portion of the test signal in a first switched position (42) while unblocking the transmission branch (28) for the measuring radiation in a second switched position (42?). According to the invention, the switching means (36) reflect the measuring radiation in a diffuse manner in the first switched position (42). Also disclosed is a method for producing such a measuring instrument.

Abstract: The invention relates to a method for the material-penetrative localization of a measurement signal, in particular a material-penetrative positioning method for use on walls, ceilings, and floors. According to the invention, a high-frequency transmitter (20, 120) emits a measurement signal (22, 122) in the gigahertz frequency range, which penetrates the material (10) at least once and is detected by a high-frequency receiver (24, 124) in order to locate the penetration position (18). The invention also relates to a device for carrying out the method.

Abstract: A locating device, in particular a hand-held locating device, for detecting objects enclosed in a medium, including an output unit for displaying at least one output variable correlated with a measuring signal of at least one sensor of the locating device, the output unit having a first dynamic range for displaying the output variable correlated with the measuring signal. At least one further dynamic range having a changed sensitivity compared to the first dynamic range is displayable via the display unit.

Abstract: The invention relates to a distance measuring device comprising a control unit. According to the invention, the control unit has a drawing mode that is used to create drawings.

Abstract: The invention relates to a device for optically measuring distance, in particular a hand-held device, comprising an transmitter unit (12) which is provided with a light source (17, 18) for transmitting optical measuring radiation (13, 20, 22) to a target object (15), and a capturing unit (14) which is arranged at a distance on the optical axis (38) of the transmitter unit (14). Said capturing unit (14) comprises at least one optical detector (54) comprising a detection surface (66) for capturing optical radiation (16, 49, 50) reflected by the target object (15). According to the invention, the detection surface (66) of the detector (54) comprises an optical near range element (68), whose optically active surface (72, 74) is elongated in the direction (61) of the radiation shift for receding target object separations (48) and expands or has at least one essentially constant extension.

Abstract: The invention relates to a device for optically measuring distance, in particular a hand-held device, comprising an transmission unit (12) which is provided with a light source (17, 18) for emitting optical measuring radiation (13, 20, 22) towards a target object (15), and a capturing unit (14) which is arranged at a distance from the optical axis (38) of the transmission unit (12). Said capturing unit (14) comprises at least one optical detector (54) for capturing optical radiation (16, 49, 50) reflected by the target object (15). According to the invention, the detector (54) of the capturing unit (14) comprises a plurality of light-sensitive surfaces (70, 72, 74; 170, 172, 174; 270, 272, 274; 370, 372; 470, 472; 570, 572) which are separated from each other and which are be activated separately. The invention also relates to a method for operating a device for optically measuring distance.