Self-monitoring sensor

The invention claimed is: 1 . A sensor configured to detect an improper installation state of the sensor, the sensor being configured as a non-invasive temperature measuring apparatus and being fastenable to a measurement object which is configured as a pipe, the sensor comprising: a holder radially spaced from the measurement object, in which at least one sensor element is received and is fixed via a compression force which is exerted by an elastic element; and a first detector, arranged in a region of the elastic element, for detecting the compression force with respect to a settable threshold value to monitor the installation state of the sensor; wherein the first detector is configured as a switch; and wherein the elastic element is configured such that the at least one sensor element moves, upon removal of the compression force, in order to actuate the switch. 2 . The sensor as claimed in claim 1 , further comprising: a second detector mounted on the measurement object of the holder for detecting a spatial orientation of the holder. 3 . The sensor as claimed in claim 1 , further comprising: a third detector for detecting a mechanical stress state arranged in a region of the fastener and mounted on the sensor; wherein the holder is fastened to the measurement object via the fastener. 4 . The sensor as claimed in claim 3 , wherein the third detector is configured as one of a strain gauge which is arranged on the holder or the fastener and a fiber Bragg grating. 5 . The sensor as claimed in claim 1 , further comprising: a thermal coupling element which is fastenable to the measurement object; and fourth detectors received in the thermal coupling element for detecting a temperature distribution to recognize a proper installation on the measurement object. 6 . The sensor as claimed in claim 5 , wherein the fourth detectors are configured as temperature sensors which are received in the thermal coupling element parallel to the measurement object. 7 . The sensor as claimed in claim 5 , wherein the fourth detectors are arranged symmetrically to a radial direction of the holder. 8 . The sensor as claimed in claim 5 , wherein the fourth detectors are arranged symmetrically to a radial direction of the holder. 9 . The sensor as claimed in claim 5 , further comprising: a fifth detector which is configured to detect an electrical variable in a circuit and which comprises at least two fastener via which the sensor is connectable to the measurement object. 10 . An operating method for a sensor configured as a non-invasive temperature measuring apparatus, the sensor comprising a holder in which a sensor element is received which is fixable by a compression force exerted by an elastic element, the method comprising: a) providing the sensor in an active operating state; b) detecting the compression force acting upon the sensor element; c) recognizing an improper installation state of the sensor if the compression force which is detected in step b) falls below a settable threshold value; and d) outputting a warning regarding the improper installation state to at least one of a user and a higher-order control unit. 11 . The operating method as claimed in claim 10 , wherein during step b) a spatial orientation of the sensor is detected, and during step c) an improper installation state of the sensor is recognized if the spatial orientation of the sensor detected in step b) deviates from a settable tolerance. 12 . The operating method as claimed in claim 11 , wherein during step b) a mechanical stress state on a surface of the holder, a thermal coupling element or a fastener via which the sensor is fastened on a measurement object, is also detected via a third detector, and during step c) an improper installation state of the sensor is recognized if a mechanical stress of the mechanical stress state falls below a settable limit stress. 13 . The operating method as claimed in claim 12 , wherein during step b), an electrical variable of a circuit which comprises at least two fasteners of the sensor is also detected, and during step c) an improper installation state of the sensor is recognized if the electrical variable detected in step b) deviates quantitatively by a settable tolerance value from a reference value. 14 . The operating method as claimed in claim 11 , wherein during step b) a temperature distribution in the thermal coupling element of the sensor is detected, and during step c) an improper installation state of the sensor is recognized if the temperature distribution detected in step b) deviates by a settable tolerance span from a reference distribution. 15 . The operating method as claimed in claim 11 , wherein during step b), an electrical variable of a circuit which comprises at least two fasteners of the sensor is also detected, and during step c) an improper installation state of the sensor is recognized if the electrical variable detected in step b) deviates quantitatively by a settable tolerance value from a reference value. 16 . The operating method as claimed in claim 10 , wherein during step b) a mechanical stress state on a surface of the holder, a thermal coupling element or a fastener via which the sensor is fastened on a measurement object, is also detected via a third detector, and during step c) an improper installation state of the sensor is recognized if a mechanical stress of the mechanical stress state falls below a settable limit stress. 17 . The operating method as claimed in claim 16 , wherein during step b) a temperature distribution in the thermal coupling element of the sensor is detected, and during step c) an improper installation state of the sensor is recognized if the temperature distribution detected in step b) deviates by a settable tolerance span from a reference distribution. 18 . The operating method as claimed in claim 10 , wherein during step b) a temperature distribution in the thermal coupling element of the sensor is detected, and during step c) an improper installation state of the sensor is recognized if the temperature distribution detected in step b) deviates by a settable tolerance span from a reference distribution. 19 . The operating method as claimed in claim 18 , wherein during step b), an electrical variable of a circuit which comprises at least two fasteners of the sensor is also detected, and during step c) an improper installation state of the sensor is recognized if the electrical variable detected in step b) deviates quantitatively by a settable tolerance value from a reference value. 20 . The operating method as claimed in claim 10 , wherein during step b), an electrical variable of a circuit which comprises at least two fasteners of the sensor is also detected, and during step c) an improper installation state of the sensor is recognized if the electrical variable detected in step b) deviates quantitatively by a settable tolerance value from a reference value. 21 . The operating method as claimed in claim 10 , wherein the sensor is configured as a non-invasive temperature measuring apparatus and is fastenable to a measurement object which is configured as a pipe. 22 . A control unit for monitoring a sensor system which comprises a sensor configured as a non-invasive temperature measuring apparatus, the sensor being couplable to the control unit, the control unit comprising: a processor; and memory; wherein the control unit is configured to: a) provide the sensor in an a