JPH01167184A - Winder for cheese - Google Patents

Abstract

PURPOSE: To prevent a defect in forming a cheese and qualitative reduction caused in inertial rotation of the cheese by providing apparatuses for increasing a yarn crossing angle in inertial rotation of the cheese more than a yarn crossing angle finally possessed by the cheese. CONSTITUTION: Apparatuses 41 to 51 are provided to increase a yarn crossing angle in inertial rotation of a cheese 2 more than a yarn crossing angle finally possessed by the cheese 2 for nondefective winding work. That is, a central unit 51 keeps a speed of an electric motor 43 constant by controlling a frequency converter 41 at winding time. While a sensor 49 detects a rotating speed of a shaft 4, a control device 48 controls a frequency converter 42, in its turn, an electric motor 33 of a traversing mechanism 11 according to an inertial rotation characteristic of the cheese 2. In this case, the winding ratio existing in inertial rotation is adjusted so as to become smaller than the winding ratio preset to winding work before starting inertial rotation on the basis of the inertial rotation characteristic of the cheese 2.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention is characterized in that the yarn to be wound is
It relates to a winder for cheese, especially randomly rolled cheese, of the type fed to the rotating cheese.

BACKGROUND OF THE INVENTION Conventional winders are subject to defects during cheese formation and deterioration of quality during cheese freewheeling.

OBJECTS TO BE SOLVED BY THE INVENTION An object of the present invention is to prevent defects during cheese formation and deterioration in quality that occur during the smooth rolling of cheese.

Means for Solving the Problems The present invention was able to solve the above problems by the configuration set forth in claim 1. Conventionally, it has been common practice to maintain the same yarn crossing angle as during winding operation during inert rotation, or to not consider the yarn crossing angle at all.

Effects of the Invention The present invention has the advantage that, in particular, when a belt device equipped with a thread entrainment section is used as a separating thread guide mechanism, it is possible to prevent thread collapse and other defects. In such cases, the present invention can greatly contribute to improving the quality of rolled cheese.

Advantageously, said device gradually reduces the winding ratio starting from the winding ratio it last had due to the operating speed of the winding operation during free-wheeling.

In this case the effect is good and sudden changes in the winding ratio are avoided.

According to a further development of the invention, the device is configured in such a way that the traversing mechanism is shut off only after the cheese drive has been shut off or after free-wheeling has started. The deceleration of the traversing motion is performed with a slight delay. This has a positive effect on cheese formation, as the threads are held away from the edges of the cheese.
No yarn collapse occurs at all.

Example An embodiment of the invention is shown in the drawing and will be explained in detail below.

FIG. 1 shows a part of a machine for producing cheese 2, designated as a whole by 1.

A shaft 4 of a drive roller 5 is mounted rotatably in the direction of the arrow 6 in a stationary machine frame (3). The drive roller 5 drives the cheese 2 by friction. The pivotably hung cheese frame 7.7' rotatably supports the sleeve 8 of the cheese 2, which rotates in the direction of the arrow 9 (FIG. 2).

The thread 10 to be wound around the cheese 2 is drawn off from a supply member (not shown here), for example a spinning tip, and then passes through a traversing mechanism, indicated in its entirety by the reference numeral 11, and partially wraps around the drive roller 5. , and then rides onto the cheese 2 as specifically shown in FIG.

The traverse mechanism 11 is arranged on the machine frame 12. Machine frame 1
2 is in the form of a plate, on the back side of its vertical end, bearings 13 and 14 for the machine frame 12 are arranged. The bearings 13 and 14 are connected to two guide rods 16 and 1
It is placed on 7. The guide rods 16 , 17 are located horizontally one above the other and are fixed to the machine frame 3 . Double arrow 18 indicates the traverse direction or traverse direction.
is shown.

The traversing mechanism 11 includes a tension member 2 in the form of an endless belt.
It has a tension member transmission 19 with 0. The tension member 20 is guided via idle rollers 21, 22, 23, 24, 25 and is driven by a drive roller 26.

Guide roller 21. 22.23.24.25 is axis 27
．． 28.29.30.31. Each shaft is coupled to a machine frame 12. The drive roller 26 is fixed to the shaft 32 of an electric motor 33. The electric motor 33 is fixed to the back side of the machine frame 12 by its flange 34.

Said rollers have a first tension member section 20' in which the tension member 20 can move from left to right in the traverse direction within the traverse movement region and another tension member section 20' in which the tension member 20 can move from right to left in the direction opposite to the traverse direction. The tension member section 20'' is arranged to form a tension member section 20''.

A yarn guide plate 35 with a concave leading edge is mounted on the machine frame 12 perpendicularly to the direction of travel of the yarn 10, so that - at the end of the traverse position 36, 37, which is illustrated in dash-dot lines, Lift up thread 10. As a result, the yarn is removed from the yarn entraining section of the tension member section 20'' running in the opposite direction to the traversing direction, for example from the yarn entraining section 38, and immediately thereafter the yarn 10 is moved from left to right in the traversing direction. The thread is carried by the thread-carrying part of the running tension member section 20', for example by the thread-carrying part 39, and is now carried from left to right in the traverse direction to the traverse end position 3γ.At this traverse end position 37, the thread is taken Part 3
9 releases the thread 10, after which the thread 10 is entrained by the next thread entraining section 40. The thread entraining sections 38, 39, 40 are distributed at equal intervals over the entire length of the tension member 20. The thread-carrying part consists of a protrusion projecting forward from the tensioning member, and the protrusion has a steeply sloped side face facing in the direction of the thread. The sides of the thread-carrying section are reinforced with a metal shell and protected against wear.

The shaft 4 is driven by an electric motor 43.

The electric motor 43 is a frequency-controlled motor like the electric motor 33 of the traversing mechanism 11.

The electric motor 33 is connected via a line 44 to a frequency converter 42 , while the electric motor 43 is connected via a line 45 to a frequency converter 41 . Both frequency converters 41 , 42 have a common control device 48 , which is connected by a line 46 to a sensor 49 . The sensor 49 is responsive to four convex markings 50 equally distributed around the axis 4 which emit a pulse each time they pass the sensor 49. These pulses are counted in the controller 48. The counting results are reflected in the starting characteristics of the shaft 4, the driving roller 5, and the cheese 2 placed on the driving roller 5.

For controlling the electric motor 33 of the traversing mechanism 11, a control program is stored in the control device 48 according to FIG. This control program runs until just before the start of inertia rotation.
For winding operation up to time t1, code 52
It is incorporated so that the winding ratio n/f shown by the line is applied. And the winding ratio n/f indicated by numeral 52
gradually decreases as the winding process progresses when randomly rolling cheese is rolled up frequently, but this decrease does not appear on the drawing in Figure 6 because the time period in question is short. , it is safe to assume that this winding ratio maintains a constant value in practice within the relevant time period.

The control device 48 is programmed in accordance with FIG. 6 to implement the invention, and the traverse speed of the traverse mechanism 11 during free rotation is formed depending on the free rotation characteristics of the cheese 2, and varies from tl to t2. The winding ratio n/ during the free rotation period of
f is the winding ratio n/f during the winding operation before the start of inertia rotation
The size is also set to be smaller.

If this condition were not met, the take-up ratio would be effectively constant during the time interval in question, as indicated by the dashed horizontal line at 52 in FIG.

The take-up ratio n/f, which means the number of rotations per reciprocation of the traversing mechanism, is gradually decreased from time tl to time t2. Symbols 52 and 53 are the winding ratio n/f
It is not a quantitative value.

A central unit 51 connects the two frequency converters 41.41 and the control device 48 to each other and is used at the same time for the power supply. Power is supplied to the central unit 51 via a conductor 47 .

The central unit 51 controls the frequency converter 41 to keep the speed of the electric motor 43 constant during winding. sensor 49
detects the rotation speed of the shaft 4, and the control device 48 controls the frequency converter 42 and the electric motor 33 of the traversing mechanism 11 according to the inertial rotation characteristics of the cheese 2.
This occurs in wheat with a virtually constant winding ratio as shown in 2.

However, from time t1 to time t2, controller 48 controls frequency converter 42 to adjust the winding ratio so that it decreases along a curve 53.

The control device 48 can selectively initiate a cut-off or free-run of the traversing mechanism 11 only after the cheese drive has been cut off or after the free-run from t1 to t2 has started. It would also be possible to continue operating according to this recipe, for example for some time, without reducing the traversing speed adapted to the winding operation.

Depending on the particular case, it may be advantageous to measure the rotational speed of the cheese 2 directly rather than indirectly.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention, in which Fig. 1 is a front view of the winding device, Fig. 2 is a sectional view taken along the line FIG. 3 is a diagram showing the progress of the winding ratio. DESCRIPTION OF SYMBOLS 1... Machine, 2... Cheese, 3... Machine frame, 4... Axis, 5... Drive roller, 6... Arrow, 7
．． 7'...Cheese frame, 8...Sleeve, 9.
...Arrow, 10... Thread, 11... Traverse mechanism, 12.
...Machine frame, 13゜14...Supporting member, 16.17...
・Guide rod, 18... Double arrow, 19... Traction 1 drive device, 20... Traction medium, 20', 20''... Traction strand, 21-25... Guide roller, 26.
... Drive roller, 27-32 ... Shaft, 33 ... Electric motor, 34 ... Flange, 35 ... Thread guide plate, 3
6.37...End part, 38 degrees 39.40...Year entraining part, 41.42...Frequency converter, 43...Electric motor, 44-47...Conducting wire, 48... control device, 49
...sensor, 50...marker, 51...central unit, 52.53...winding ratio, tl, t2...time

Claims (1)

[Claims] 1. Defects in cheese winders of the type having a controllable traverse mechanism operated along the cheese, in which the thread to be wound is fed to the rotating cheese by a thread guide mechanism. A device (from 41 to 5
In order to control the traverse speed of the traverse mechanism (11) during inertial rotation, the device (41 to 51)
Based on the inertial rotation characteristics of cheese (2), during inertial rotation (t1~
The winding ratio existing at t2) is the inertial rotation (t1 to t2)
A cheese winder, characterized in that the winding ratio is configured to be smaller than the winding ratio set for the winding operation before starting.