CS222909B1 - Apparatus for rational remedy of non-stationary state of open-end spinning units - Google Patents

Abstract

The invention relates to an auxiliary device for open-end spinning. It solves the technical problem of making the travel of a piecing unit as efficient as possible. In the method according to the invention, the piecing unit movable along the spinning units of the open-end spinning machine serves for rectifying a non-stationary state of the spinning units, the running direction of the unit being controlled by a decision means in combination with a discrimination means for the purpose of determining an efficient travel of the unit in the direction of the next one spinning unit or of a plurality of spinning units which are in the non-stationary state. The discrimination means can be formed by a system of trigger circuits accommodated on the spinning units, whilst the decision means is formed by a logical circuit for recording the non-stationary state of the spinning unit and for determining the efficient running direction of the piecing unit. The device for carrying out the method provides the necessary switching means.

Description

The invention relates to a device for the rational removal of the non-stationary state of spinning units arranged on one or both sides of an open-end spinning machine by means of a service spinning unit traveling around these units.

In order to eliminate the non-stationary state of the spinning units, i.e., those units which, due to the failure caused by most of the yarn being broken off, are put out of operation, according to the prior art, two completely different procedures are used using automatic mechanisms.

The first ροβ ^ μρ solves this problem by individual automation and is known, for example, 173 768 a / 168 224. In this case, each spinning unit is provided with its own means for breaking the tear, i.e. an individual electromagnetically actuated fiber feeding coupling to the winding device. take-up and take-up rollers for take-up and take-up of the spun yarn onto a spool and then a reversing clutch for reciprocating the take-up and take-up rollers necessary to return the broken yarn end to the spinning unit. The advantage of this process is the rapid removal of the non-stationary state of the spinning unit and thus a high percentage of utilization of its production capacity. The disadvantage is the high cost of the machine with individually automated spinning units.

The second procedure is to use the so-called group automation known eg from the patents of the FRG δ. 2,008,142 and 20X2108, according to which a group of spinning units on one or more machines bypasses the piecing unit and stops with an unsteady state. Here, it detects the yarn end on the bobbin of the unit, opens, cleans and closes the yarn generating device, introduces the desired yarn end into the machine, starts feeding the fibers and restores normal yarn withdrawal from the spinning unit by tilting the yarn bobbin. Compared to 8 individual automation, group automation is less expensive, but its major disadvantage is the large production loss for units with non-stationary state that are out of

222 909 wagon as long as they reach. there will be no pH-spike of the spinning loop. The loss on production is tm greater. the more frequent the occurrence of an unsteady state on the spinning units, the faster the machine spins and the larger the group of spinning units is assigned to the operator of the spinning unit ·

SUMMARY OF THE INVENTION It is an object of the present invention to eliminate the above-mentioned pH time delays by group automation and to find a solution to reduce downtime of non-predominant spinning units, and to provide a device for implementing such a solution.

According to the invention, this object is achieved by means of a rational removal of the non-stationary state of the spinning units by means of a piecing aggregate, the principle being that the piecing mechanism of the piecing aggregate is controlled by resolution and decision means. breaker sensors of the spinning units for obtaining stationary or non-stationary signals and forming buses closed to the flip-flop circuit inputs, a closed circuit, while the decision means is a logic circuit arranged on the spinning aggregate and connected by its wires to the bus and discriminator wires.

According to the invention, it is advantageous if the logic circuit of the decision means consists of a clock generator for transmitting the verification pulses, a trimmer for transcribing signals of stationary or unsteady state to one or zero, central memory and memory locations for registering and testing these signals. for commands to the controllers for determining the rational direction of travel of the piecing unit ·

If there is an accidental occurrence of the same distance of the spinning rods in the non-stationary wire on both sides of the piecing path of the piecing aggregate, its logic circuit will give a signal to travel to the unit in the original piecing direction of the piecing aggregate.

1 is a cross-sectional diagram of a spinning unit; FIG. 2 is a plan view of an open-end suction machine with multiple spinning units and with an exemplary travel path of the spinning assembly around the machine; FIG. exemplary - schematic design of a spinning aggregate with a logic circuit and a discriminating means on a machine part with several spinning machines

222 909 units, Fig. 4 is another exemplary embodiment of the travel path of the piecing aggregate when operating multiple open-end spinning machines ·

According to FIG. 1, a fiber sliver 2 is fed to the spinning unit 1 and is fed by a pair of feed rollers 10 to a disintegrating and forming device 6, where the fibers are disintegrated and shortened and then discharged in the form of yarn A by a pair of take-off rollers. In the case of a yarn break (unsteady state), the yarn touch sensor divides both the signal 8 for stopping the fiber feed by the feed rollers J, and the signal 10, whose function will be explained later.

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According to the exemplary embodiment shown in FIG. 2, the spinning unit 11 is moved around the open-end spinning machine with the spinning units 1 in the travel direction za in order to remove the non-stationary state of these units. 3- to the next unit. 8, so that the unit C, also with the non-stationary state, does not reach up to. According to the invention, however, it chooses a rational travel solution to the unit C before continuing in the original travel direction. in the S direction and removes the non-stationary state of the unit in place B · The saved time can then be used on the unit to operate another open-end spinning machine, thereby achieving considerable savings for this expensive one. apparatus·

In the exemplary embodiment of FIG. 3, each spinning unit 1 is equipped with a flip-flop 12 - with synchronous input D, adjusting input S, clock input T, asynchronous input V and output 2 · Flip-flops are interconnected by conductors 22 through outputs D and outputs £ a forms a closed circuit (circular shift register) on the machine · The spinning aggregate 11 is connected to this circuit by its conductor 14 at its Čirniooti ·

Furthermore, the flip-flops 12 are connected by their inputs T and 6 to the buses 13a and 13b. It also connects the piecing unit 11 to the buses with their wires 15 and 16.

The logic circuit 17 of the piecing aggregate 11 consists of a clock generator 18 for sending verification pulses to the bus 13a, and a central memory 19 with memory locations for registering information from the conductor 14 '. 18 · The operating controller determines the rational direction of travel of the piecing aggregate 11 · Furthermore, in the logic circuit 17 there is a tripping device 21 connected - to the bus 13b by a conductor 16 ·

Asynchronous inputs in flip-flops 12 are connected to the break-8 sensor contact, which is in a non-stationary state

-222 909 of the spinning unit 'disconnects and fits the corresponding signal 10 to the asynchronous output V of the flip-flop 12 due to the yarn breakage.

The adjusting inputs S of the flip-flops 12 are connected via a bus 13b to a tripping device 21, which sends an impinge to the flip-flop inputs of the spinning units 1 by switching from the input V to the flip-flop output 12 in the form of one (non-stationary) or zero (stationary state).

the operation of the piecing aggregate according to the exemplary embodiment takes place as follows:

1. During its' travel around the spinning units 1 in the S direction, the spinning unit 11 arrives at a non-forward unit 1, which is brought into an operating (stationary) state (obi? 3) in a known manner »»

2. The decision means formed by the logic circuit 17 on the piecing assembly 11 sends a pulse through the conductor 16 to the bus 13b and thus to all the inputs S of the flip-flops 12, thus opening the way from the asynchronous input V to the output. information about the stationary or non-stationary state of the spinning unit in the form of zero or one.

3 · The clock generator 18, in cooperation with the central memory 19, sends sequential clock signals to the clock inputs X of all the flip-flops 12 connected to the circular shift register, whereby information about stationary or non-stationary gradually appears at the flip-flop input. state of all spinning units .1

4. The central memory 19 connected to the input D of the flip-flop 12 by the conductor 14 stores this information in memory locations whose addresses, with the order of the spinning units from the city of the spinning unit position to the left, gradually

222 909 around the entire machine up to the spinning unit immediately to the right of the spinning unit position.

After storing information from all spinning units connected by their flip-flops 12 to a circular shift register, the central memory 19 tests the memory locations from the beginning of the memory (to the left) and from the end of the memory (to the right). On the basis of this test, the command of the operation controller 20 of the piecing aggregate 11 leads to the resultant rational travel direction.

In a similar manner, the piecing aggregate can select rational travel when operating multiple machines according to the exemplary embodiment of FIG. 4 by testing each side of the machines I, II, III sequentially by means of the discriminating and decision means during its bypass in the S direction. machines on which it detects spinning units in a non-stationary state. After these units are brought into operation, they return to the S-path and continue to circulate around the sidewalls of the machines.

This rational travel avoids the loss of time that still has been caused by the purposeless travel of the piecing aggregate around all the spinning units of the machines, regardless of whether they are in a non-stationary state. The time saved on the unproductive travel can therefore be used to operate a larger number of spinning units, thereby achieving greater efficiency for the spinning units currently in use.

222 909

1 · Equipment for rational removal of non-stationary state of spinning units of open-end spinning machine

Claims (2)

BACKGROUND OF THE INVENTION comprising a machine-side device on the travel path and an unsteady-state device for individual spinning units, characterized in that the drive means is a driving fitting, wherein the distinguishing means is a system of conductors (22) interconnected flip-flops (12). ) connected by their inputs (V) to break sensors (8) of spinning units (1) for obtaining stationary or non-stationary signals and forming buses (13a, 13b) connected to inputs (T, Q) of flip-flops (12) closed circuit while the decision means is a logic circuit (17) arranged on the spinning unit (11) and not connected by its wires (14, 15, 16) to the buses (13a, 13b) and the wires (22) of the discriminator. Device according to claim 1, characterized in that the logic circuit (17) of the decision means consists of a clock pulse generator (18) for transmitting verification pulses, of a tripping device (21) for transcribing stationary or non-stationary signals to one or zero; from a central memory (19) with memory locations for registering and testing these signals, as well as issuing commands to the drive controllers (20) to determine the rational travel direction of the piecing aggregate