SE455820B - DEVICE FOR DETECTING THE SLAUGHTER LEVEL IN A METAL BATH - Google Patents

Description

455 820 2 accuracy is in the order of i2.5 cm.

The present invention aims to provide a device of the type initially described, which allows accurate detection of the upper surface of the slag layer with an accuracy of at least 0.5 cm. Furthermore, the device must be able to be used repeatedly a number of times without reducing the measuring accuracy.

The characteristic of the invention is that an antenna is arranged in the tip of the lance in order to receive hum signals, preferably network hum. A hum detector is electrically connected to the antenna and emits a signal when the hum is detected. In a preferred embodiment of the invention, the hum detector is an electrical circuit of the type used in touch control of lighting. When the antenna is at a distance from the melt, no signal is emitted from the detector, but when the tip of the antenna comes into physical contact with the upper surface of the slag layer, the detector emits an output signal.

The lance is preferably fixed in a holder which at a constant speed, e.g. via a stepper motor, the lance and the antenna attached to the end of the lance move down towards the metal bath. the position the lance occupies at the moment the output signal is emitted.

Instead of using a free-standing antenna. which is electrically isolated from the lance, in accordance with the above, can serve as an antenna the wires of a conventional thermocouple, which are conventionally enclosed by a layer of quartz. The entire thermocouple unit is arranged projecting from the end surface of the lance and is protected by a metal cover.

The invention will be described in more detail below in connection with the accompanying drawings, in which Fig. 1 shows a conventional lance provided with an antenna according to the invention, Fig. 2 shows the end of a lance provided with an alternative embodiment of the antenna, fig. Fig. 3 shows the device according to the invention combined with an inductive sensor of known type, and Fig. 4 shows a circuit diagram for the equipment of the per se known electrical circuit for detecting hum.

Fig. 1 shows a typical set with a container 1, so-called torpedo sideboard, which is filled with molten metal. A slag layer is formed on the upper surface of the metal and it is now desired to measure the degree of filling of the container by measuring the level of the upper surface of the slag layer using a conventional lance 2 which is lowered towards the metal bath by means of a stepping motor 3 at a constant speed. The lance is supported in an elongate housing 4 which in a manner known per se is fixed in a frame 5, which is pivotable over the container.

A control equipment, generally denoted by 6, controls the movements of the stepper motor. The control equipment 6 also comprises a number of per se known electrical circuits, which by means of wires are in electrical connection with measuring means, which are arranged in and on the lance. Examples of such measuring means are thermocouples, inductive sensors, means for measuring oxygen in the metal bath, etc.

The lance can also be of the type which in its front part 7 comprises a sample chamber, which is immersed in the metal bath in order to receive a sample. Conventionally, the front portion 7 of the lance consists of a thick-walled cardboard tube. An antenna 8 of electrically conductive material is arranged in the front end surface of the lance electrically isolated therefrom.

In Fig. 1, the antenna is in the form of a straight rod and is connected by means of an electrical line (not shown) to a hum detector arranged inside the housing 4, which on a signal line (not shown) 4s 820, 4 emits an electrical signal to the control equipment 6 when the antenna's capacitive connection to the slag layer gradually increases and the tip of the antenna finally comes into physical contact with the upper surface of the slag layer.

Fig. 2 shows an alternative antenna design. The antenna here consists of a conventional thermocouple 9 which is fitted in the end surface of the front portion 7 of the lance 8. The thermocouple consists of two wires 10, ll of different materials, which are in contact with ll are enclosed in a quartz tube 12 That of the units 10-12 formed each other at the tip of the thermocouple. The wires 10, U-shaped thermocouple 9 are surrounded by a protective cover 13 of metal cylindrical body 14 with a neck 15, which is intended for the protective cover and the thermocouple to be supported by an insertion in the front end surface of the lance 2. Reference numerals 16 and 17 refer to electrical wires intended to be connected to an electrical cable running inside the lance, which is routed to the control equipment 6. The cable is connected to the hum detector. The output signal of the detector is used partly for the calculation of the level of the slag layer and partly for controlling a switch (not shown) which, after the output signal is emitted, switches and now connects the cable (not shown) to another of the above-mentioned measuring means, e.g. a temperature sensor. With continued downward movement of the lance, the temperature in the slag layer and the metal bath is then measured.

Fig. 3 shows an arrangement similar to that of Fig. 2 with the addition that the lance is provided with an inductive sensor 18. When the lance is moved downwards and the antenna comes into contact with the upper surface of the slag layer, a signal is given to a counter which counts the step motor 3 traveled step - based on a reference value - and whose value is now read. The lance continues its downward movement, measuring the temperature, and when the sensor 18 reaches the interface between the metal bath and the slag layer, the inductive sensor emits a signal to the control equipment 6 in a known manner and now the value of the counter is read again.

From the two read values, the thickness of the slag layer is calculated. 455 820 5 _ Fig. 4 shows the wiring diagram of the hum-sensitive detector.

In this case, the detector is connected to detect mains hum. The heart of the detector is a circuit 20 known per se in connection with touch control of lighting. The antenna 8 is connected via a single conductor 21 to one 22 of the two adaptive inputs 22, 23 of the circuit. A capacitor 23A adapts the circuit 20 for detection. of the upper surface of the slag layer. A second capacitor 24 connects the antenna to the same reference level as the circuit 20 otherwise has and which is formed at the supply voltage source of the circuit, which consists of a transformer T whose primary side is connected between phase and zero to the mains and whose secondary side is connected to the circuit 20. A resistor Between the phase of the network and the "earth" determines said reference potential, in this case 7.5 volts.

Thus, the antenna 8 is at the same potential as the reference potential and follows this in the event that the mains voltage would vary. The second adaptive input 23 of the circuit is similarly connected to the reference potential via a capacitor 26. The mains voltage is sensed at input 23.

The circuit also comprises a zero-crossing detector, which at an input 27 senses the zero-crossings in the alternating voltage on the secondary side of the transformer T. The circuit 20 comprises a clock generator which generates a short internal strobe pulse, which coincides with the positive zero crossings for the voltage at the input 27. The strobe pulse goes to a control logic included in the circuit 20. The control logic responds to signals from the antenna input 22 and the mains detector input 27 only during the strobe interval, i.e. during the positive zero reviews.

The control logic compares the signals on the antenna input 22 and the mains voltage input 23 with each other only during the strobe interval, and if three consecutive comparisons show that the signals on the input 22 and on the input 23 match, a noise signal is considered present and an output signal is output at the circuit 20. the inputs 22, 23 have the advantage that the sensitivity of the detector is automatically adapted to the hum level present on the antenna. As a result, the detector becomes rather unrecognizable for the design of the antenna. The above-described embodiments of the invention can be modified and varied in many ways within the scope of the basic idea of the invention. For example, the antenna 8 does not have to be arranged on a lance but can just as easily sit at the end of a rope, which lies over a block and which is celebrated downwards until the antenna comes into contact with the bath.

Claims (7)

455 820 7 PATENT REQUIREMENTS Device for detecting the slag level in a metal bath, comprising a measuring probe (2) guided towards the metal bath with detection means, characterized by an antenna (47 5, 6) arranged at the probe for receiving hum, preferably net hum, in the vicinity of the antenna and a hum detector (23) connected to the antenna arranged to emit at its output (22) an output signal indicating the mechanical contact of the antenna and thus the measuring probe with the slag layer. Device according to claim 1, characterized in that the antenna is an exposed metal rod (4) projecting from the tip of the probe, electrically isolated from the probe. Device according to claim 1, characterized in that the antenna is a thermocouple (5, 6L) arranged at the probe. 4. Device according to claim 1, characterized in that the detector is arranged to compare the antenna signal with an alternating voltage related to the mains frequency only at the zero crossings of the alternating voltage and that when matching said signals during a predetermined number of consecutive zero crossings, the said the output signal. 5. Device according to claim 1, characterized in that the detector is a circuit used in touch control of lighting, known per se. Device according to one or more of the preceding claims, characterized in that the probe is a lance (2). Device according to claim 1, characterized in that the lance (2) is provided in a manner known per se with an inductive sensor (14) for determining the level of the interface between slag and molten metal, whereby measuring the thickness of the slag layer is allowed by comparing the output signal of the detector with an output signal from the inductive sensor (14L