CS273518B1 - Sensor of ferromagnetic material's especially ropes' cross section instantaneous and gradual decrease - Google Patents

Abstract

The existing sensors of magnetic flaw detectors are unfavourable for dependences of the signal on the measurement speed and measuring errors by the impact of outer ferromagnetic materials. The sensor sensitive to gradual and instant losses of the cross section of ferromagnetic materials, especially ropes, uses the Hall probe or other converter of the magnetic field into the electric voltage, which is located in the measuring magnetic head, and, between the poles of the magnetic head, consists of the magnetic circuit of the detector of the gradual loss of the cross section of ferromagnetic materials with the first Hall probe, inside which the magnetic circuit of the instant loss of the cross section of ferromagnetic materials with the second Hall probe is arranged. The distance between the poles of the magnetic circuit of the detector of the gradual loss of the cross section equals a half of the length of the distance of the magnetic head and the distance of the poles of the magnetic circuit of the detector of the instant loss of the cross section is many times smaller than the distance of the poles of the magnetic circuit of the detector of the gradual loss of the cross section. The poles of the magnetic circuit of the detector of the instant loss of the cross section are equipped with inserts, while the magnetic head, magnetic circuit of the detector of the gradual loss of the cross section and magnetic circuit of the detector of the instant loss of the cross section are arranged in the shape of a disc and are split and the magnetic circuit of the detector of the gradual loss of the cross section consists of at least one Hall probe.<IMAGE>

Description

Known magnetic defect detectors are particularly disadvantageous for raising the signal for rapid measurement and measurement errors due to external ferromagnetic materials. Sensors sensitive to both gradual and instantaneous cross-sectional losses of non-ionic materials, especially ropes, use a hall probe or other magnetic field transducer located in the measuring magnetic head, has a magnetic circuit of a gradual cross-sectional loss sensor with the first hall a probe inside which the instantaneous loss sensor of the instantaneous loss sensor is connected with the second hall probe; gradual loss of cross-section. The instantaneous loss sensor's magnetic circuit poles are provided with inserts, the magnetizing head, the slow-loss sensor's magnetic circuit, and the instantaneous loss sensor's magnetic circuit are disc-shaped and divided, and the sensor's magnetic circuit after the loose cross-section has at least one first hall probe.

CS 273 518 Bl

The invention relates to a sensor for gradual and instantaneous loss of cross-section of ferromagnetic material, in particular ropes.

Magnetic defect detectors are known as measuring coils, bifilar or with a ferromagnetic core, in which inductive transducers are located. Hall sensors and associated hall and inductive sensors are also known. The disadvantage of sensors with inductive converters is the dependence of the signal on the test speed. Sensors are known which have magnetic sensors as part of a magnetizing head, such as PLR Patent No. P 252 268, CA No. 1,038,037 and US Patent No. 4,096,437. Their drawback is the considerable influence of external ferromagnetic materials on measurement errors.

The aforementioned drawbacks are reduced by the sensor of gradual and instantaneous loss of cross-section of ferromagnetic material, in particular of ropes, according to the invention, which consists in that the magnetic circuit of the sensor of gradual loss of cross-section with a first hall probe is placed between the instantaneous loss of sensor cross-section with the second hall probe. The pole distance of the magnetic circuit of the soft-drop sensor is half the pole length of the magnetizing head. The pole distance of the magnetic circuit of the instantaneous loss of cross-section sensor is several times smaller than the pole distance of the magnetic circuit of the slow-loss section sensor. The magnetic circuit poles of the instantaneous loss of cross-section sensor are provided with inserts. The magnetizing head, the sensor of the gradual loss sensor and the sensor of the instantaneous loss sensor are disc-shaped and divided. The magnetic circuit of the gradual loss sensor comprises at least two first hall probes. The instantaneous loss sensor transducer magnetic circuit comprises at least two second hall probes.

The sensor according to the invention has the advantage that it is sensitive to both gradual and instantaneous cross-sectional loss of ferromagnetic materials, with the phase-shifted difference in sensed signals suppressing the disturbance background when measuring the instantaneous cross-sectional loss caused by external strand strands. The length of the sensor is smaller in its configuration and reduces the influence of external ferromagnetic materials on measurement errors.

In the drawing there is shown schematically a sensor for measuring the gradual and instantaneous loss of cross-section of a ferromagnetic material according to the invention in an embodiment for measuring ropes. Inside between the poles of the magnetization head 4 is located the magnetic circuit of the sensor of gradual loss of cross section 2 r. By the first hall probe inside which is located the magnetic circuit of the sensor of instantaneous loss of cross section 3 with second hall probe 6. the pole distance length of the magnetizing head 6. Pole distance of the magnetic sensor circuit instantaneous drop-section 2 is many times smaller than the distance of the poles of the magnetic sensor circuit gradual loss of cross section 2 nojvýhodnčjší is also a distance less than the diameter of the cable 2 · PFI changes in diameter of the rope 2 j ^sou poles of the magnetic sensor circuit instantaneous drop-section 2 provided with linings 2 P ^ro maintaining the same sensitivity. For measuring the cross-sectional loss of a ferromagnetic material with a circular cross-section, for example, the ropes 2, the magnetizing head 6, the magnetic circuit of the instantaneous loss-of-cross-section sensor 3 are disc-shaped and are divided into at least two segments. The sensor's magnetic circuits can be equipped with a larger number of hall probes to increase the useful signal, possibly increasing the number of individual segments.

Claims (7)

SUBJECT OF THE INVENTION A sensor for gradual and instantaneous loss of cross-section of ferromagnetic material, in particular ropes, using a hall probe or other magnetic field transducer located in a measuring magnetic head, characterized in that a magnetic circuit of the sensor of gradual is located between the poles of the magnetizing head (4) a cross-sectional drop (2) with a first hall probe (7) inside which is located the magnetic circuit of the instantaneous cross-sectional drop sensor (3) with a second hall probe (6). 2. The sensor according to claim 1, characterized in that the pole distance of the magnetic circuit of the sensor of gradual loss of the cross-section (2) is half the pole length of the magnetizing head (4). Sensor according to Claims 1 and 2, characterized in that the pole distance of the magnetic circuit of the instantaneous loss of cross-section sensor (3) is several times smaller than the pole distance of the magnetic circuit of the slow-loss section of the cross-section (2). Sensor according to one of Claims 1 to 3, characterized in that the poles of the magnetic circuit of the instantaneous loss sensor (3) are provided with inserts (5). Sensor according to one of Claims 1 to 4, characterized in that the magnetizing head (4), the magnetic circuit of the sensor for gradual loss of cross-section (2) and the magnetic circuit of the sensor for instantaneous loss of cross-section (3) are disc-shaped and divided. Sensor according to one of Claims 1 to 5, characterized in that the magnetic circuit of the sensor for gradual loss of cross-section (2) comprises at least two first hall probes (7). Sensor according to one of Claims 1 to 6, characterized in that the magnetic circuit of the instantaneous loss sensor (3) comprises at least two second hall probes (6).