ITMI961769A1 - DEVICE ON A MACHINE FOR THE PREPARATION FOR SPINNING IN PARTICULAR AN IRON TO MEASURE THE THICKNESS OF A NESTRO - Google Patents

Description

DESCRIPTION OF THE INDUSTRIAL INVENTION

The invention relates to a device on a spinning preparation machine, in particular a drawing frame, for measuring the thickness of a composite card sliver, which device consists mainly of a funnel-shaped body surrounding the card sliver which passes through it and is arranged immediately in front of a pair of extraction cylinders, the measurement values of the apparatus being transmitted to control devices, in which the funnel-shaped body has a recess on its end section for the '' housing of an inwardly loaded, movably supported member, the inner end of which forms a constriction with the opposite wall for the composite card sliver passing through it and whose position variation for different thicknesses of the composite card sliver acts on a transducer device for generating command pulses.

In a device known from DE-OS 2358941, the movable member is made as a leaf spring, ie made of elastic steel. Due to the friction of the composite card strip at the high output speed of the strip on the drawing frame, for example 1000 m / min and more, the feeler blade is subject to wear during operation.

It is therefore an object of the invention to create a device of the type described above, which eliminates the aforementioned drawbacks, which in particular has a high resistance to wear of the feeler blade during operation and a greater duration connected thereto.

The achievement of this object is achieved by means of the distinctive features of claim 1.

Through the use of a ferroalloy of hard material, the feeler blade is both workable and also hardenable. You can start from a semi-finished product, for example in the shape of a ribbon. Since the basic mass of the material is made of steel, a certain elasticity necessary for deformation is obtained. Since the steel is also well machinable by chip removal or by shearing, it is possible to easily obtain a feeler blade from the strip, for example in the form of a double lever. Subsequently, the steel base mass is hardened by heating and quenching, possibly with subsequent tempering. Together with the exceptionally high hardness of the hard material alloy, the hardened steel base mass gives the feeler blade a high wear resistance. Due to the fact that the ferroalloy of hard material is machinable and hardenable, a great advantage is achieved both in the manufacturing technique and also in the application technique, i.e. good machinability is combined with exceptional wear resistance due to the high hardness. By tempering the hardness is adjustable so as to prevent breakage during operation. Thanks to the high mechanical resistance, the feeler blade can be small, i.e. light, in structure. The feeler blade during operation, in particular at high speed, must react quickly to fluctuations in the thickness of the web, i.e. it advantageously has a small inertia. The small inertia is also facilitated by the fact that the hard ferroalloy material has a considerably lower specific weight than that of steel. The percentage of steel advantageously provides high strength and good machinability, while in combination with this the titanium carbide content provides high wear resistance and at the same time results in lower inertia due to the lower specific weight. , so that a fast reaction capability of the feeler blade is ensured. Furthermore, the metallic material has a good thermal conductivity, which is of great importance, because in operation temperatures up to 400 ° C can be reached.

Conveniently, the hard ferroalloy material (ferrotitanium) contains up to about 50% by volume of titanium carbide, because the material up to this percentage can be worked without problems.

Other advantageous embodiments of the invention are represented in claims 3 to 9.

The invention will be better clarified in the following with reference to examples of embodiments represented in the drawing.

They show:

Figure 1, schematically, side view of a drawing mechanism of a drawing frame with a web collecting element, a web guide and a web funnel (measuring funnel) at the unloading of the drawing mechanism;

Figure 2, sectional side view of the measuring funnel - with feeler blade and antagonist element of hard ferroalloy material - and of the compartment with the inductive displacement detector and a fitting for the insufflation air, and

Figure 3, section A - A of the measuring funnel with feeler blade according to Figure 2.

According to Figure 1, the drawing mechanism is a drawing frame, for example a high-power drawing frame HSR Triitzschler, conceived as a 3 out of 3 drawing mechanism, i.e. it consists of three lower cylinders I, II, III (I lower output cylinder, The lower intermediate roller, III the lower inlet roller) and three upper cylinders 1, 2, 3. The card strips are stretched in the stretching mechanism. The draft consists of a pre-stretch and a main draft. The pairs of cylinders 3 / III and 2 / II form the pre-stretch field, and the pairs of cylinders 2 / II and 1/1 form the main stretch field. At the outlet of the stretching mechanism 4 there is a collection element 5 with a funnel-shaped passage 6 for the concentration of multiple card belts so as to form a ribbon-like composite card belt. Downstream of the collecting element 5 there is a transfer element 7 for guiding the ribbon-like composite card sliver from the collecting element 6 to a funnel of the belt 8, from which the compressed card sliver is extracted at high speed by means of two extraction cylinders 9, 10. Between the transfer element 7 and the funnel of the belt 8 a turbulence nozzle 11 is provided for introducing the belt 8 into the funnel at the beginning. The transfer element 7 is arranged inclined downwards in the direction of the funnel of the belt 8. A indicates the direction of flow (working direction) of the fiber material (not shown).

Figure 2 shows the device on a drawing frame for measuring the thickness of a composite card sliver, which device mainly consists of a funnel of the sliver 8 surrounding the composite card sliver which passes through it and is placed immediately before the pair. of extraction cylinders 8, 10, the measurement values of the apparatus being transmitted to control devices (not shown) where the funnel of the belt on its end section has a recess for housing a loaded feeler blade 12, movably supported, the inner end of which forms with the opposite wall a constriction for the composite card web passing through it and whose position variation for different thicknesses of the composite card web acts on a transducer device (inductive displacement detector 13) for generating control pulses. The feeler blade 12 is designed as a two-arm lever and is rotatable around a rotary support 14. The lever arm 12a is directly engaged in the fiber material to be felt, the lever arm 12b is loaded by a spring 15. At the arm opposed by lever 12a is an adjustable antagonist element 16, fixed during operation. The feeler blade 12 engages through a slit opening 17 in the wall surface of the funnel of the belt 8 (see Figure 3). On the side not facing the fiber material, a fixed abutment element 19 is opposed to the lever arm 12a, a gap 20 being provided between the lever 12a and the abutment element 19. The antagonist element 16 engages through a slot opening (not shown) in the wall surface of the belt funnel 8.

The feeler blade 12 and the antagonist element 16 are made of ferrotitanium (hard ferroalloy material) and are therefore wear resistant compared to the composite card strip passing through the measuring funnel 8 at high speed. The feeler blade 12 has little inertia and reacts quickly to fluctuations in the thickness of the web.

A closed container 18 is associated with the funnel of the tape 8, in whose internal compartment the inductive displacement detector 13 is substantially found, consisting of a reel 13a and mobile core 13b; the movable core 13b is movably fixed to the lever arm 12b. The internal compartment 18a of the container 18 and the interspace 20 form a compartment which is traversed by a current of insufflation air. For this purpose, a connection union 21 is connected to the wall of the container 18, which is connected to a source of compressed air (not shown) by means of a flexible pipe 22. The insufflation air stream B passes through the connection nozzle 21 into the internal compartment 18a, passes through the internal compartment as an insufflation air stream C, then passes through the interspace 20 as an insufflation air stream D and exits finally in the atmosphere.

According to Figure 3, narrow slits 23a, 23b are provided between the feeler blade 12 and the walls of the funnel of the belt 8. The blowing air stream D ensures that the interspace 20 and the slots 23a, 23b remain free from suspended fibers, dust or the like. At the same time, the blowing air currents C and D cool the inductive displacement detector 13 and the feeler blade 12.

Claims (9)

CLAIMS 1. Device on a spinning preparation machine, in particular a drawing frame, for measuring the thickness of a composite card sliver, which device substantially consists of a funnel-shaped body surrounding the composite card sliver which is passes through and is arranged immediately in front of a pair of extraction cylinders, in which the measured values of the apparatus are transmitted to control devices, the funnel-shaped body having a recess on its end section for the housing of a movably supported, inwardly loaded member, the inner end of which forms with the opposite wall a constriction for the composite card web passing through it and whose position variation for different thicknesses of the composite card web acts on a device transducer for the generation of command pulses, characterized in that the movably supported member (12) consists of at least partially from hard ferroalloy material. 2. Device according to claim 1, characterized in that the movably supported member is a spring-loaded feeler blade (12). Device according to claim 1 or 2, characterized in that the feeler blade (12) is designed as a rotatably supported lever. Device according to one of claims 1 to 3, characterized in that the hard ferroalloy material contains titanium carbide. Device according to one of claims 1 to 4, characterized in that the hard ferroalloy material contains up to 50% by volume of titanium carbide. Device according to one of claims 1 to 5, characterized in that a measuring transducer, for example an inductive displacement detector (13), is associated with the feeler blade. Device according to one of claims 1 to 6, characterized in that an adjustable antagonist element (16) is opposed to the feeler blade (12), which is at least partially made of hard ferroalloy material. Device according to one of claims 1 to 7, characterized in that the contact surface of the card strip with the feeler blade (12) and / or with the antagonist element (16) is made of hard ferroalloy material. Device according to one of claims 1 to 8, characterized in that the device is arranged at the outlet of a drawing frame.