FI77325C - Device for measuring the suspension of a conductor in a vulcanization pipe. - Google Patents

Description

77325

Device for measuring the deflection of a line in a caning tube vu1. -An ordning fätning av nedhängningen av en ledare i ett vulkaniseringsrör.

The present invention relates to a device for measuring the deflection of a wire sheathed in an insulating layer in a vulcanizing tube, the device having an excitation coil connected to an AC voltage source surrounding the line in the vulcanizing tube. Generating an electric current in the line and at least two magnetic field measuring senses a reference device connected to the line and spaced apart next to the vulcanization tube and to the measuring sensors, which generates a position signal corresponding to the deflection of the line.

One such device is known (DE-PS 2 521 278).

By means of the transformer core placed in the winding tube, alternating current is inductively supplied to the line. By means of at least two magnetic field measuring sensors arranged at a radial distance from the conductor and at a distance from each other, the change in the difference indicates not only the magnitude of the deflection but also the direction of the deviation. In this case, the transformer: and the measuring sensors of the magnetic field are expediently placed in a so-called measuring tube, which is adapted to the passage of the vulcanized drop tube.

The transformer of this known device requires a transformer core in the form of a plate pack or the like. It must therefore be placed in a suitable manner in the measuring tube. The measuring elements of the magnetic field, preferably in the form of air core sides, must also be suitably adapted to the recesses of the measuring tube. Therefore, this known device is relatively expensive and gives sufficiently accurate measurement results.

It is an object of the present invention to provide an apparatus for improving the measurement of the deflection of a wire sheathed with an insulating layer in a vulcanization tube, starting from a large reduction in material and manufacturing costs.

According to the invention, this object is solved by providing an AC voltage source, an excitation coil and magnetic field measuring sensors for use at high frequencies, and that the reference device comprises a gear discriminator and generates a position signal from the phase difference of the measuring signals.

: The device according to the invention provides an inertial deflection measurement according to the principle of measuring the travel time. The high-frequency voltages induced in the magnetic field sensor have a different phase state from the reference voltage when the line spacing from the measuring sensors is not the same. The reason is the different travel time of the magnetic field due to the measuring sensor. Thus, high-frequency measurement sense signals have a phase shift, the magnitude of which is a measure of the deviation of the line from its neutral position. In addition, the direction of the deflection deviation can be detected from the sign of the phase shift.

Since the device according to the invention is operated by a high-frequency switching voltage source, the cost of applying current to the cable conductor and measuring the magnetic field generated by the current is very low. The measurement frequency is preferably between 100 and 500 MHz. It allows the smallest possible dimensions for both the excitation ---- coil on the generator side and the measuring sensor element 11e, which according to an embodiment of the invention are receiving coils. The distance between the switching and receiving coils is preferably more than 1.5 m, in order to prevent the coupling of the alarm coil from being connected directly to the receiving coils.

: - Due to the use of high frequencies, the core of the transformer can be dispensed with and the excitation coil can be formed by a single turn. There must also be only one in the receiving coils; . only round. The distance between the receiving coils can also be smaller than the maximum diameter of the pipe. However, in this case, a higher frequency must be selected to achieve a sufficient phase difference of 3 77325 with position offsets. However, a change in the distance between the receiving coils is in many cases necessary in order to operate in an industrially advantageous frequency range. The total cost of the operation is therefore very small.

The costs can be further reduced by providing an electrical connection between the flanges of the colliding pipe sections according to the invention, that an electrically conductive member is connected to the first flange at a distance from this electrical connection, but is passed through the second flange in particular, and that the conductive member and the second flange are combined coaxial cable core, outer conductor; with time. In the usual way, the vulcanization tube provides effective protection so that no magnetic field caused by the conductor can form outside it. However, a seal, which is not a conductive material, is placed in the usual way between two colliding pipes. Therefore, a magnetic field may also be present from the outside in this sealing area. In the case of a preferred embodiment of the present invention, the flanges are pulled together to form a receiving lead loop. The circuit of this receiving loop is closed by an electrical connection between the flanges and an electrically conductive member. The most suitable electrically conductive connection between the flanges is one connecting bolt. Usually, however, several connecting bolts are used to tighten the pipe flanges together. This allows the take-up reel to be constructed simply and does not require any changes in the vulcanization tube except for the electrically conductive member and the connection of the coaxial cable to the flange.

In order to determine the phase shift of the measurement sensing signals, different switching devices are possible. According to an embodiment of the invention, it is further provided that a high-frequency controlled electronic switch is connected in front of the phase discriminator, which periodically outputs the measurement sensing signals to the phase discriminator for export. In order to perform 4 77325 simple phase shift measurements, according to an embodiment of the invention, it is arranged in such a way that a parallel resonant circuit is connected in each case to the inputs of the phase discriminator. The control of an electronic switch, for example a semiconductor switch, also takes place at a high frequency, for example 100 kHz.

Like the receiving coils, the excitation coil can be arranged between the flanges of the vulcanization tube sections, through a gap filled with sealing material, in order to induce a high-frequency electric line ·· '.

The device according to the invention not only significantly reduces costs, but also has the advantage of high dimensional accuracy. An amplitude comparison is performed in a known device. However, the amplitude of the signal decreases with the square of the distance. As a result, nonlinearities arise in the amplitude measurement when measuring the deflection. In contrast, the travel time of the signal is proportional to the distance. Therefore, the measurement error in the device according to the invention is smaller in magnitude than in the known device.

An embodiment of the invention will be explained in more detail below with reference to the drawings.

Figure 1 shows a section of two pipe sections flanged together with receiving coils.

Figure 2 shows a block diagram of a reference circuit according to the invention.

Before looking in more detail at the details shown in the drawings, it should first be mentioned that each of the features described or shown alone or in combination with the features of the claims is essential to the invention.

5,77325

The bare conductor wire or conduit 10 is coated in an extruder (not shown) with the material 11. The coated conduit 10 is passed to a vulcanization tube 12, where the vulcanization of the insulating material 11 under heat and pressure is performed in a known manner. In the actual flotation zone 12, of which only a short part is shown, the insulating layer 11 is still relatively soft, so that, if possible, all mechanical contact with this insulating layer must be avoided. In order to obtain a uniform coating, the line must be routed, if possible, centrally in the vulcanization tube 12.

Figure 1 shows two interconnected pipe ends 13, 14 with a flange 13 resp. 16. These flanges are pressed against each other by bolts 17, whereby several bolts 17 are arranged at circumferential intervals. In order to seal the inner part of the pipe, a seal 18 is shown, which is shown only diagrammatically. An excitation coil (not shown) is arranged in the axial distance between the flanges 15, 16, which is formed, for example, by a single turn arranged between the flanges at the other end of the tube. This is the case, for example, at the other end of the tube 13. The axial distance is at least 1.5 m. The excitation coil is connected to a high-frequency voltage source with a frequency of about 100 to 500 MHz.

Non-uniformly, a metal rod 19 is guided inside the bolt 17 through the bore of the flange 16 and screwed into the dummy hole of the flange 15. The insulation 20 surrounds the rod 19 in the drilling area of the flange 16 up to the flange 15. The free end of the rod 19 is connected to the lead-in 21 of the coaxial cable 22, the outer conductor 23 of the coaxial cable of which is connected to the flange 16. In this case, there is a single-loop lead loop, the passage of which is shown by line 24.

The excitation coil provides a high frequency current in the line 10 which provides a high frequency magnetic field which, through the dielectric seal 18, can extend outwardly 77325 and thus induce a voltage in the line 24. The voltage signal conducted by the coaxial cable 22 can be suitably utilized. The two diametrically or at least spaced conductor loops thus generate two voltage signals, their phase state depending on the propagation distance the magnetic field must travel from the conductor to the conductor loop 10. At the same time, i.e. at the neutral position of the line 10, the phase difference is zero. The larger the deviation of the line 10 from the neutral position, the greater the phase difference. The maximum phase difference is more suitably + 90 °.

Therefore, the measuring frequency must then be adjusted appropriately, in which case, of course, the diameter of the vulcanization tube also becomes a parameter.

Fig. 2 schematically shows an electronic switch 30, the two inputs 31, 32 of which are connected, for example, to a measuring coil according to the structure shown in Fig. 1. A control signal with a frequency of, for example, 100 kHz is applied to the electronic switch via the control line 33. The output of the electronic switch 30 is in the mixer 34, where the signals from the coils 1 and 2 are rectified and int er f the difference: - with the signal of the interference oscillator 35. Therefore, an impulse is generated at the output of the mixer 34: sequences which may have a different phase state from the phase state of the oscillator voltage. The impulse chains are amplified in the VT amplifier 36 and applied via a second electronic switch 37 to the inputs 38 of the gear discriminator 40, respectively. 39. The inputs 38, 39 are further connected to the parallel resonant circuits 41 resp. 42, which, as narrowband filters, also continue the oscillations to the switching pauses without a deviation worth mentioning the amplitude. The shift discriminator then determines the deviation, i.e. the phase state between the measurement signals of the coils 1 and 2, and indicates it in the pointing device 43.

By means of the described measuring device, each deviation of the line 10 from the desired calculated state is determined by means of a phase shift 77325 between the measuring coil signals. Of course, the measurement signals obtained for the deflection of the line can also be used to provide an adjustment, in order to automatically adjust the desired deflection in each case. The deflection measurement signal is compared with the value given as an actual signal in the control device, and the control deviation is utilized to control the control member to change the deflection.

Claims (9)

77325 A device for measuring the deflection of a wire sheathed in a special layer in a vulcanization tube, the device comprising an excitation coil surrounding the line in the vulcanization tube, which generates an electric current in the line and at least two magnetic field measuring sensing means a reference device connected to each other next to the vulcanization tube and to the measuring sensors, which generates a position signal corresponding to the deflection of the line, characterized in that an AC voltage source, excitation coil and magnetic field measuring sensors are provided for Device according to Claim 1, characterized in that the excitation coil and / or the magnetic field measuring sensors (24) are in each case arranged in the region of the flange (15, 16) of the tube ends (13, 14) of the vulcanization tube (12). Device according to Claim 2, characterized; that the magnetic field measuring sensors are receptacles. Device according to Claim 3, characterized in that an electrical connection (17) is provided between the flanges (15, 16) of the colliding pipe ends (13, 14), the distance from this electrical connection (17) being connected first. an electrically conductive member (19) with the electrical flange (15), but passing in isolation (20) through the second flange (16) and that the electrically conductive member (19) and the second flange (16) are connected to the core of the coaxial cable (22). , floating with wire. 9 77325 Device according to Claim 4, characterized in that the conductive element is a metal rod (19) wound on the first flange (15) and passed through a bore in the second flange (16). Device according to Claim 4 or 5, characterized in that the electrical connection between the flanges (15, 16) is formed by a connecting bolt (17). Device according to one of Claims 1 to 6, characterized in that a high-frequency controlled electrical switch (37) is connected in front of the gear discriminator (40), which periodically provides magnetic field measurement sensing signals to the inputs (38, 39) of the phase discriminator (40). Device according to Claim 7, characterized in that a parallel resonant circuit (41, 42) is connected to the inputs (38, 39) of the gear discriminator (40). Device according to Claim 7 or 8, characterized in that the measurement sensing signals are applied to separate inputs (31, 32) of a second electronic switch (30) connected to the input of a rectified mixing cascade (34), in which a high-frequency signal is mixed with the magnetic field measurement sensing signals. . 77325