EP1362939A2 - Roving feeding apparatus comprising a special worm gear - Google Patents

Abstract

An open-ended spinning assembly has a swivel-action fibre band feed cylinder with a helical gear engaging with a shaft-driven worm gear. The helical gear esp. has an overlain peak profile to ensure immediate engagement by the worm gear. The helical gear (23) is esp. transposed on the shaft (24) with respect to a symmetrical plane (42) at right angles to the drive shaft (24). The plane (42) intersects the lowest point (45) in the overlain gear thread (41), along the drive shaft (24) axis with respect to the worm gear (22) centre axis (44) swivel plane (43). The gear further has a pre-positioning assembly (30) which presents the worm gear (22) in a position which is determined by the distance (x) by which the helical gear (23) is transposed. The worm gear (22) teeth (35) then swivel accurately into the helical gear (22) thread. A worm gear tooth (35) centreline (33) is presented at an angle theta (f) to the worm gear swivel plane (43), as determined by the transposition (x) value. The value theta is calculated using the formula f = sin 72asterisk (x/2)

Description

The invention relates to a sliver feed device for an open-end spinning device according to the preamble of Claim 1.

Sliver feeders for open-end spinning devices are state of the art in various embodiments.

In connection with open-end rotor spinning machines, it is known, for example, to close the individual spinning devices during the spinning operation by means of a pivotably mounted cover element, which has a sliver feed and opening device.
This means that these cover elements each have, inter alia, a bearing bracket for a sliver opening roller and a bearing bracket for a sliver feed cylinder, with a worm wheel that can be connected via an electromagnetic clutch being arranged at the end of the shaft of the sliver feed cylinder.
When the spinning device is closed, this worm wheel meshes with a worm which is fixed on a machine-long, constantly rotating drive shaft of the rotor spinning machine.
When the spinning device is open, the worm wheel and worm are arranged at a distance, that is, the worm wheel and worm are in engagement.

Has this type of driving a sliver feed cylinder has proven itself in practice.

When swiveling the worm wheel back into the worm However, difficulties may occasionally arise for example due to increased wear of the Make the worm wheel noticeable.

An open-end spinning device in which these difficulties are to be avoided is described in DE-AS 23 14 229. In this known open-end spinning device, a swivel housing, which accommodates a fiber sliver feed cylinder and an opening roller, is mounted on a separate swivel axis arranged at a distance from the machine-long drive shaft. The sliver feed cylinder, the axis of rotation of which runs parallel to the central axis of the machine-long drive shaft, is connected to the machine-long drive shaft via a special intermediate shaft, which has a gear wheel at the end.
When the spinning device is opened, the gearwheel of the intermediate shaft slides out of an associated gearwheel that is permanently installed on the machine-long drive shaft.
In order to minimize the switching and frictional resistances between the gears when closing the spinning device, the swivel axis, the machine-long drive shaft and the intermediate shaft are arranged so that when the spinning device is closed, an approximately tangential sliding of the gear arranged on the intermediate shaft onto the gear of the machine length Drive shaft takes place.

This well-known, relative in its construction complicated spinning device has become in practice however not proven and could therefore in the Do not enforce the textile industry.

EP 0 672 767 A1 also describes an open-end spinning device with a pivotably mounted cover element, into which a sliver feed and opening device is integrated, and the pivot axis of which is arranged at a distance from a machine-long drive shaft of the rotor spinning machine.
In this known open-end spinning device, too, the sliver feed cylinder is driven by a worm wheel which meshes with a worm which is fixed on a continuously rotating, machine-long drive shaft.
This means that the worm wheel of the sliver feed cylinder corresponds to the associated worm of the drive shaft when the spinning device is closed and is spaced apart from this worm when the spinning device is open.

To ensure proper drive of the sliver feed cylinder, the worm wheel and worm have the same pitch, as usual.
This means that the pitch of the worm wheel in the area of the pitch circle diameter relevant for the drive corresponds exactly to the pitch of the worm gear.
From this fact, however, it follows that the pitch of the worm wheel in the area of the tip circle diameter is greater than the pitch of the worm gear, so that when the worm wheel is pivoted into the worm, a situation could arise in which two teeth of the worm wheel simultaneously have two threads of the worm spill over, which would make a further swiveling of the worm wheel impossible.

In order to avoid this case and to facilitate the immersion of the worm wheel into the worm when the spinning device is closed, EP 0 672 767 A1 provides for the worm gear of the worm to be provided with a special threading contour and for the worm to be arranged on the drive shaft such that a The plane of symmetry of the worm, which results from the threading contour, among other things, corresponds exactly to the swivel plane of the central axis of the worm wheel.
This means that the worm gear has a so-called overlay profile, the pitch of which corresponds exactly to the pitch of the worm wheel in the area of the tip circle and which is designed and arranged in such a way that the thread turns of the worm always run out at one point.
This ensures that when the worm wheel is pivoted in, one of the teeth of the worm wheel always dips between two turns of the worm gear.

In practice, however, it has been shown that with such designed and arranged worm gears, a proper immersion of the worm wheel in the worm is guaranteed, but that such worm gears no longer have optimal carrying behavior due to the reduction in the effective contact surfaces in the area of the thread turns of the worm.
This means that in these known worm gears with an overlay profile in the area of the worm gear, the worm wheel no longer rotates quite evenly. In addition, the individual teeth of the worm wheel are stressed much more than with "normal" worm gears.

The somewhat dirty running of the worm wheel leads to this Fluctuations in sliver feeding while the strong Stresses on the worm gear teeth to an increased Wear of the worm wheel leads.

Starting from the aforementioned prior art, the invention is based on the object of improving the known sliver feed devices.
In particular, the sliver feed is to be evened out and the service life of the worm wheel is to be increased, although it must be ensured that when the spinning device is closed the worm wheel can always be pivoted into the rotating worm without problems.

This object is achieved by a Sliver feed device solved, as in claim 1 is described.

Advantageous embodiments of the invention are the subject of Dependent claims.

The embodiment according to the invention has in particular the advantage that the axial displacement of the one Overlay profile equipped snail on their Drive shaft, that is, by moving the worm orthogonal to the swivel plane of the worm wheel, the Carrying behavior of the worm gear significantly improved will what is positive both on the concentricity of the Sliver feed cylinder as well as on the life of the Worm wheel affects.

In order to achieve a flawless despite this displacement of the screw Swiveling the worm wheel into the worm ensure a positioning device is provided that the worm wheel is always pre-positioned so that it is secured is that never two teeth of the worm wheel at the same time can overlap two flight turns of the snail.

As stated in claim 2, the positioning device provides making sure that the central axis of one of the teeth of the Worm wheel with respect to the pivot plane of the central axis of the Worm wheel at a given positioning angle is arranged. The positioning angle depends on Measure of the displacement of the screw and chosen so that the The worm wheel can always be swiveled in safely.

The optimal positioning angle of the tooth can be calculated in a simple manner using the formula described in claim 3.
The angular alignment of the teeth of the worm wheel ensures that pinching or the like cannot occur when the worm wheel is immersed in the worm.
That is, the pre-positioning, as already explained above, reliably precludes the fact that, despite the axial displacement of the worm, two teeth of the worm wheel can slide simultaneously over two adjacent thread turns of the worm.

As set out in claim 4, the positioning device for precisely aligning the teeth of the worm wheel has at least one magnet fixed to the bearing housing of the electromagnetic clutch and a ferromagnetic positioning element which is connected in a rotationally fixed manner to the worm wheel of the worm gear, which is disengaged when the spinning device is open and so that it can be freely rotated.
An embodiment has been found to be particularly advantageous in which at least one permanent magnet is used (claim 5).
Such a permanent magnet does not require any additional energy supply and nevertheless automatically ensures a correct, safe alignment of the positioning element and thus a reliable adjustment of the angular position of the teeth of the worm wheel.

According to claim 6, the positioning element is designed as a positioning disk which has a plurality of radially projecting positioning lugs, each of which is influenced by the magnetic force of the permanent magnet.
This means that the positioning lugs corresponding to the permanent magnet always reliably ensure a predetermined, angular alignment of the teeth of the worm wheel when the worm wheel is immersed in the worm.

As indicated in claim 7, the number corresponds to Centering approaches preferably the number of teeth of the Worm wheel. This ensures that always one of the positioning approaches in the scope of the Permanent magnet stands and from this into a defined one Position is pivoted.

The invention is based on one in the drawings illustrated embodiment explained in more detail.

Fig. 1

eine Offenend-Spinnvorrichtung mit einem schwenkbar gelagerten Deckelelement, in das eine Faserbandzuführeinrichtung integriert ist, in geschlossenem Zustand,

Fig. 2

die Offenend-Spinnvorrichtung gemäß Figur 1, in geöffnetem Zustand,

Fig. 3

das Schneckengetriebe zum Antreiben des Faserbandzuführzylinders sowie die erfindungsgemäße Positioniereinrichtung zum winkelgenauen Ausrichten der Zähne des Schneckenrades, in einem größeren Maßstab,

Fig. 4

das Schneckengetriebe gemäß Fig.3 im eingeschwenkten Zustand, das heißt während des Betriebes.

It shows:

Fig. 1

an open-end spinning device with a pivotably mounted cover element, into which a sliver feed device is integrated, in the closed state,

Fig. 2

1, in the open state,

Fig. 3

the worm gear for driving the sliver feed cylinder and the positioning device according to the invention for the angular alignment of the teeth of the worm wheel, on a larger scale,

Fig. 4

the worm gear according to Figure 3 in the pivoted state, that is, during operation.

An open-end spinning device 1 of a rotor spinning machine is shown schematically in FIGS. As is known, such spinning devices 1 have a spinning box housing 2 which is fastened to the base frame of the rotor spinning machine (not shown in more detail) by means of fastening means 3.
A console 4 is generally fastened to the spinning box housing 2 and accommodates a support disk bearing 5, an axial bearing 6 and a rotor housing 7.
In the rotor housing 7, which is pressurized by a pneumatic line 8 and connected to a corresponding vacuum source 9, a spinning rotor 10 rotates at high speed and is supported with its rotor shaft 11 in the wedge gaps of the support disk bearing 5.
As is known from the prior art, the rotor shaft 11 is acted upon by a tangential belt 12 which is set against the rotor shaft 11 by means of a tensioning roller 13.

The rotor housing 7, which is open on its front side, is during the spinning process by a cover element 14 locked. That is, on the front of the rotor housing 7 there is a channel plate 15 fastened in the cover element 14, preferably a replaceable duct plate adapter 16 having. There is one in the channel plate adapter 16 Thread take-off nozzle 17 and the mouth area of a so-called Fiber guide channel 18 arranged.

In addition to the channel plate 15, the cover element 14, which is movably mounted on a swivel axis 19, also has a device 20 for feeding and releasing a sliver (not shown).
In addition to a fiber sliver feed cylinder 21, an opening roller 26 and the fiber guide channel 18 are accommodated in the cover element 14.
The sliver feed cylinder 21 is connected via a worm gear, which consists of a worm wheel 22 and a worm 23, to a machine-long, constantly rotating drive shaft 24.
That is, on a shaft 36 of the sliver feed cylinder 21, a worm wheel 22 is attached at the end, which meshes with one of the worms 23 on the stationary, rotatable drive shaft 24.

In the shaft 36 is also a definable switchable Electromagnetic clutch 25 turned on, which makes it possible to Requires the worm wheel 22 and the sliver feed cylinder 21 functionally separate.

As shown, the opening roller 26 is driven via a constantly rotating tangential belt 28, the one Rear drive whorls 27 of the opening roller 26 applied.

FIG. 1 shows the spinning device 1 of a work station of the rotor spinning machine during the spinning process.
That is, the rotor housing 7 of this spinning device 1 is closed by the cover element 14.
In this operating state, the worm wheel 22 of the sliver feed cylinder 21 is in engagement with the worm 23, which is positively or non-positively connected to the rotating drive shaft 24, and the drive whorl 27 of the opening roller 26 bears against the circumferential tangential belt 28.

FIG. 2 shows the corresponding spinning device 1 out of operation.
That is, the cover element 14 of the spinning device 1 was pivoted about the pivot axis 19 in the direction of arrow A and the rotor housing 7 was thereby opened. In this state, the rotor housing 7 is easily accessible from the front, for example for cleaning the rotor 10.

As can be seen, in this operating state the drive whorl 27 of the opening roller 26 is lifted off the tangential belt 28 and the worm wheel 22 of the sliver feed cylinder 21 is positioned at a distance from the worm 23 of the stationary drive shaft 24.
The path S shown in dashed lines in FIG. 2 shows the path covered by the worm wheel 22 during the opening of the spinning device 1.

FIGS. 3 and 4 show the positioning device 30 according to the invention, which ensures that when the spinning device 1 is closed, the teeth 32 of the worm wheel 22 in question are aligned in precise angle, taking into account an axial offset of the worm 22.
A situation is indicated in FIG. 3 in which the worm wheel 22, which, as mentioned above, is connected via a shaft 36 and an electromagnetic clutch 25 to the sliver feed cylinder 21 of the spinning device 1, shortly before being immersed in one of the worms 23 machine-long, stationary, rotating drive shaft 24 is.
This means that the spinning device 1 in question is close to the complete closure of the rotor housing 7 by the cover element 14.

4 shows the worm gear 22, 23 when closed Spinning device, that is, during the operation of the Spinning device 1.

As indicated in the figures, a worm wheel 22, which has a plurality of teeth 32, is arranged at the end on the shaft 36 of the sliver feed cylinder 21.
The pitch circle of the worm wheel 22 is identified by 39, the associated tip circle of the worm wheel 22 by 38.

The measure of the pitch of the teeth 32 in the area of the pitch circle is with t and the measure of division in the range of Head circle labeled T.

The positioning device 30 essentially consists of a permanent magnet 37 fixed, for example, on the bearing housing 31 of an electromagnetic clutch 25, and of a ferromagnetic positioning element 34, which is connected to the worm wheel 22 in a rotationally fixed manner.
The positioning element is preferably designed as a positioning disk 34 and has radially projecting positioning lugs 35 which correspond to one or more permanent magnets 37.

The permanent magnet 37 is arranged such that the positioning lugs 35 of the positioning disk 34 always fix the teeth 32 of the worm wheel 22 in the position shown in FIG. 3.
That is, when the worm wheel 22 is immersed in the worm 23, the central axis 33 of one of the teeth 32 of the worm wheel 22 is always arranged at a positioning angle ϕ to the pivot plane 43 of the central axis 44 of the worm wheel 22. The positioning angle ϕ, which can easily be calculated using the formula: ϕ = 72 * sin (x / 2), depends on the dimension x of the offset of the worm 23 relative to the swivel plane 43 of the worm wheel 22.
The dimension x of the displacement of the worm 23 results from the engagement conditions of the worm gear.

The worm 23 has flight turns 41 with a pitch t and an originally trapezoidal cross-sectional shape. The gear turns 41 are cut by an overlay profile 40, which has a pitch T and is thus matched to the pitch of the tip circle diameter 38 of the worm wheel 22.
The overlay profile 40 is arranged in such a way that each aisle turn 41 ends in a cut edge and a plane of symmetry 42 intersects a base point 45 arranged centrally between two turn turns 41.

As indicated in Figure 3, the dimension x of the offset the distance between the pivot plane 43 of the worm wheel 22 and the itself in the area of the screw 23 due to the Overlay profile 40 resulting perpendicular to Drive shaft 24 arranged plane of symmetry 42.

As already explained above, the axial Offset of the worm 23 by the dimension x a worm gear created, which is characterized by good wearing behavior and thus characterized by a very even sliver feed. In addition, the pre-positioning of the worm wheel 22 reliably avoided that two teeth 32 of the worm wheel 22 simultaneously two adjacent gear turns 41 on the Drive shaft 24 can overlap fixed worm 23 resulting in a hindrance to the closure of the concerned Open-end spinning device or at least to an elevated one Wear of the worm wheel 22 would result.

Claims (7)

Sliver feed device for an open-end spinning device with a pivotably mounted sliver feed cylinder which can be driven via a worm gear, a worm wheel connectable to the sliver feed cylinder meshing with a worm, which is arranged on a machine-long, stationary, rotating drive shaft and has a worm gear with a threading contour , which is formed in that the gear turns are cut to prevent a tooth of the worm wheel from fitting onto a threaded head of the worm following an overlay profile,
characterized in that the worm (23) is fixed on the drive shaft (24) in such a way that a plane of symmetry (42) which is arranged perpendicular to the drive shaft (24) and which has a base point (45) of the superimposition profile (45) arranged centrally between two gear turns (41). 40) cuts, is offset with respect to a pivot plane (43) of the central axis (44) of the worm wheel (22) in the axial direction of the drive shaft (24) and
that a positioning device (30) is provided which pre-positions the worm wheel (22) depending on the dimension (x) of the offset of the worm (23) in such a way that the teeth (35) of the worm wheel (22) easily into the worm (22) are pivotable. Sliver feed device according to claim 1, characterized in that a tooth (35) of the worm wheel (22) can be positioned so that the central axis (33) of the tooth (35) with respect to the swivel plane (43) of the worm wheel (22) is below a predetermined, from Dimension (x) of the offset of the screw (23) dependent positioning angle (ϕ) is arranged. Sliver feed device according to claim 2, characterized in that the positioning angle (ϕ) can be calculated according to the formula: ϕ = 72 * sin (x / 2). Sliver feed device according to claim 1, characterized in that the positioning device (30) has at least one magnet (37) which is stationary on the bearing housing (31) of an electromagnetic clutch (25) and a ferromagnetic positioning element (34) which is connected in a rotationally fixed manner to the rotatably mounted worm wheel (22) ) having. Sliver feed device according to claim 4, characterized in that the positioning device (30) has at least one permanent magnet (37). Sliver feed device according to claim 4, characterized in that the positioning element is designed as a positioning disc (34) which has a plurality of radially projecting ferromagnetic positioning lugs (35). Sliver feed device according to claim 6, characterized in that the number of ferromagnetic positioning lugs (35) corresponds to the number of teeth (32) of the worm wheel (22).

Images