CS209279B1 - Sensor of sliver density for textile machines - Google Patents

Abstract

A sliver density sensor for textile machines, particularly drawframes comprises a stationary roller 1 and swingable measuring roller 2 mounted on one arm of a two arm cranked lever, the other arm 5 of which is coupled with both an inductance position sensor 7 and a pressing member 8 the latter of which can be formed by a spring mounted in a sleeve, which is mounted pivotally on a pin. <IMAGE>

Description

(54) Sliver density sensor for textile machines

A strand density sensor for textile machines, in particular draw-in machines, comprising a pivotable and fixed measuring cylinder.

For regulation of prestretch. the field on the drawing machines is inserted into the sliver path by a sensing device which detects the instantaneous density of the sliver and transmits a proportional signal to the stretching field regulator according to the measured deviations.

For good function of the stretching field it is important to change the signal. from the transducer, it acted on the stretch control element with the least delay. For this reason, it is necessary that the strand density sensor is located in the immediate vicinity of the prestretch field.

Pneumatic sensing devices are known but do not function reliably at higher sliver speeds. Sensors on the principle of capacity measurement work with a big error. Therefore, mechanical sensors are better used in practice.

In the known mechanical sensors, the strand passes between two measuring rollers, one of which is fixed, the other pivoting and both are driven by hand. A sensor that senses the deviations of the swinging roller and converts them into electrical quantities is located above both rollers. The rocking cylinder is pressed against. to a fixed cylinder directly or via a lever transmission.

The disadvantage of this arrangement is the considerable difficulty!

sensor measurements, caused in particular by the long lever length, which prevents its positioning in the immediate vicinity of the rolls of the stretch field. In this case, the sensor senses the actual deflection of the swivel cylinder and it must be electrically amplified. Placing the sensor above the rollers impairs the operator's ability to guide the spring and clean it.

These drawbacks are overcome by the strand sensor according to the invention, which is characterized in that the pivoting cylinder is mounted on one arm of a two-arm angular lever, with the other arm being coupled to an inductive position sensor and a thrust member.

The advantage of this arrangement is the minimum dimensions of the sensor, whose working length is given by the size of the measuring rollers and the length of the densifier. This arrangement allows very short distances; the distance between the measuring rollers and the stretching field and thus the minimum transport delay. The measuring rollers are accessible for both the feeding of the strand and for its cleaning. Position sensor- is located outside the room. The measuring cylinders and their position in the spring axis give a greater deviation and thus a higher el. value. Also the space behind the measuring rollers can be used immediately to guide the strand to the downstream device.

Further advantages and features of the invention are apparent from the description of an exemplary embodiment schematically known.

seen in the attached drawing in plan view.

In front of the fixed roller 1 and the swinging roller 2 in the direction of the passage of the strand 3, a densifier 4 is placed, through which the strand 3 passes into the space between the fixed and swinging rollers 1 and 2 which are driven by drive means (not shown). an inductive position sensor 7 and a thrust member formed by a spring 8 mounted on the piston 9, which together with the piston 9 is housed in the housing 10, are associated on the hill of the second arm of the angle lever 5. rotatably mounted on pin 11 and secured in position by pin 12.

The fixed cylinder 1 and the swivel cylinder 2, the drive of which is not shown, feed the strand 3 from a not shown one.

Claims (1)

SUBJECT A sliver density sensor for textile machines, coupled to an inductive sensor (7) of a yoke and especially to a drawing machine comprising a pivotable member. and fixed measuring. a cylinder, characterized in that the output is 2. The transducer according to method 1, the roller (2) is mounted on one arm of a double-arm J, characterized in that the pressure member is formed by a spring. angular lever (5), with the second arm of which is (8) mounted in a housing (10), which is rotatably mounted on a pin (11) . 1 shows a drawing of the prestretch field through the densifier 4 to the following. unrecognized device. ..... The spring 3 is pressed by the pivoting cylinder 2 by means of a two-arm angular lever 5 which is rotated ^: in the bearing 6 by the action of the spring 8 and the piston 9 in the housing 10. Deflection of the bi-directional angle lever 5 is sensed by the inductive position sensor 7. The magnitude of the deflection is ^; is given by the transmission of the two-arm angular lever 5. The spring 8 is located together with the piston 9 in the housing 10, which is pivotable about the pin 11 and is secured by inserting the locking pin 12. Unlocking. With the locking pin 12, the sleeve 10 can be swiveled around the pin 11, thereby allowing the two-arm lever 5 to be pivoted and the pivot cylinder 2 to be disengaged from the fixed cylinder 1 for easy insertion of the strand. I or cleaning. Housing 10 - generates long enough; a high lever for overcoming the spring resistance when rotated into the working position; which is secured with the locking pin 12.