EP0222532A2

EP0222532A2 - Hackling or combing of fibres

Info

Publication number: EP0222532A2
Application number: EP86308173A
Authority: EP
Inventors: Thomas Flanagan
Original assignee: James Mackie and Sons Ltd; Lummus Mackie Ltd
Current assignee: Lummus Mackie Ltd
Priority date: 1985-11-05
Filing date: 1986-10-21
Publication date: 1987-05-20
Also published as: EP0222532B1; EP0222532A3; SU1449015A3; GB8527226D0; CN1017732B; CN86108302A

Abstract

A bundles of fibres 32 suspended from a holder 34 is combed by co-operating arrays of pins 31,33 which are driven around closed paths defined by rollers 37, 38, 39,35,40,41. When the arrays are moved together, they form a substantially vertical working reach over which the pins in the arrays are opposed as they move in a downward direction alongside one another in order to comb the fibres. The arrays are pivoted about the lower rollers 35,37, and mechanism including cams 50, followers 51 and links 54 periodically adjusts the spacing between the co-operating arrays of pins in the working reach so as to increase the gap between them, as shown. The bundle of fibres is moved into the zone of the working reach at a time when the gap is increased and when the arrays of pins come together, combing takes place. The arrays then move apart again and a fresh bundle of fibres is introduced.

Description

This invention relates to the combing of fibres, particularly the hackling of fibres such as flax and will be described in terms of the treatment of flax, although the invention is equally applicable to the combing of other fibres. As a preliminary, the scutched flax is divided into bundles or so-called "pieces" which are fed to a hackling machine. The operation of such machines has been well known for many years, and is described in detail in, for example, The Foundations of Spinning Technology by W. E. Moreton, published by Longmans Green & Company in 1937.
As described in more detail in this book, the bundles of flax are suspended from holders which are mechanically moved along a channel extending the length of the machine, this channel itself being mounted to reciprocate in a vertical direction to lower the bundles between opposed arrays of pins mounted upon endless sheets. One sheet moves clockwise and the other anti-clockwise, so that their respective hackle pins comb the bundles in a downward direction and remove the shorter fibres (the tow) from the bundle. Each bundle is combed as it moves downwardly between the sheets in the same direction of travel as the hackle pins; it then dwells for a period at the bottom of the stroke while still undergoing combing and it then receives further combing as it is pulled up through the pins in the opposite direction to their travel as the channel supporting the holders is raised to its upper position to lift the bundles out of the sheets. The holders are then advanced one position, i.e. to the next arrays of pins which are more densely pinned, and the cycle repeated.
Each bundle of flax is normally in the region of one to one and a half metres long and is clamped approximately half-way along its length so that in the raised position, the height of the channel must be in the region of eight feet (2.5 metres) from the ground. The machine is thus a large one of which the length can be about forty feet (13 metres), the hackling section itself being in the region of twenty five feet (8 metres) in length. The revolving hackling sheets are in a fixed position.
As described in more detail in the book referred to above, the machine is double sided, the bundles of flax are clamped approximately half-way along their length in the holders at one end of the machine and the holders lowered and raised so as to cause the opposing sets of hackles to comb out the tow from the bundle and leave the higher quality "line" fibres held in the holder. After each complete vertical reciprocation of the holder it is automatically moved one position along the supporting channel and the hackling cycle repeated. The coarseness and pitch of the hackling pins become finer lengthwise on each side of the machine from the feed end and when each successive holder reaches the other end, the holder is reversed and the position of the flax within the holder re-adjusted ("pulled through") so that on the reverse travel down the opposite side of the machine the other end of each bundle including the section which had been gripped in the holder, is combed.
A traditional construction of hackling machine is illustrated in Figures 1 and 2 of the accompanying drawings, which are respectively a partial side elevation and an end view showing the raised position of the channel with the lowered or operative position shown in dotted lines.
Figure 1 shows a number of holders 4 disposed lengthwise of the machine, each with its bundle of fibres 6. As seen in Figure 2, the holders 4 are located in a channel 8 by means of pairs of studs 9 for movement along the channel under the control of a dog mechanism within the channel (not shown). The channel, in turn, is mounted on chains or straps 10 passing over wheels 12 driven to lower and raise the channel. At the opposite end of the straps are counter-balanc weights 14 to assist the raising of the channel.
Each holder 4 is in the form of opposed clamping plates held together by bolts 15 and, when inserted, the bundles are evenly spread across their respective plates. The machine is double sided, the arrangement as illustrated being duplicated on each side.
As can be seen from the drawings, each bundle is clamped approximately half-way along its length during the first passage so that when lowered, approximately forty percent of its length, normally the root end, is combed. When the holder is inverted so as to be supported by the alternative pair of pins 9 the clamp bolts are slackened and the piece is pulled further through the holder in the opposite direction to that part which has been combed so that when the top is being combed, all that part of the bundle which was not subjected to the combing during the first passage, is combed during the return passage.
Directly below the channel 8 are endless sheets which comprise a number of endless belts 16 across which are mounted successive tie bars 7 which are pitched right around the supporting belts. These bars 7 carry the pinned hackle bars 17 and there may for example, be thirty such bars around the circumference of the belts 16 at a pitch of just over two inches (50 mm). The hackle pins at one side become increasingly finer and more closely pitched as the holders progressively move along the machine, at the end of which the holders are reversed on the bend, and the pin pattern is repeated, starting coarse at the reversal end and being more densely pitched and finer as the holders return down the other side. The settings of the projecting points of the opposing pins, the overlap, if desired, the progressive fineness and density of the pins are determined to suit the quality of the material to be processed. The belts 16 pass around upper and lower rollers 18 and 19 respectively so as to define substantially vertical working reaches along which the fibres are hackled or combed and which diverge slightly towards the bottom.
As seen in Figure 1, the bars 7 span four belts 16 and are riveted to the belts at 28. On its side adjacent the belts 16 each tie bar has a number of projecting lugs 20 for supporting the hackle bars 17, only the upper of the two tie bars shown in Figure 1 having its hackle bars in position, there being a total of seven hackle bars 17 over the length of each tie bar. The hackle pins are shown only in the two left hand hackle bars, but as already described the fineness of the pinning increases along the length of the tie bars. As a result of the construction just described, tie bars 7 and hackle bars 17 alternate around the circumference of the belts 16 as can be seen in Figure 2.
The amount of hackling which the material receives varies with the number of lifts of head and the revolutions of belt per minute. By increasing the speed of the belts, the amount of work given to the material is thereby increased. An increase in the number of lifts of head per minute, the speed of the belts remaining unchanged, results in a reduction of the amount of work given to the material, but the strain on the material is increased thereby, owing to the alteration in the rate of hackling.
The speed of the head and the channels normally varies between six and ten lifts per minute and the belts 16 between eight and fifteen revolutions per minute, according to the material being worked. The aim is to drive the belts at a speed which will give maximum yield consistent with the cut and the cleanness of fibre. The function of pins in hackling machines is generally defined as that of opening, splitting and cleaning of fibre, the opening up of the bundle being accomplished by the coarse pins, the cutting by the medium pins and the cleaning by the fine pins.
The tow which is combed from the bundles is removed from the hackle pins by brushes 22 and from the brushes by pinned stripping rollers 23. The rollers 23 are cleaned in their turn by doffing knives 24 and the tow 25 finally falls into bins 26.
The full line position of Figure 2 shows the channel 8 in its raised position in which the bundles of flax 6 are lifted clear of the belts 16. The dotted line position illustrates the channel 8' in its lowered position in which the fibres are being hackled. At this lower position the channel will dwell for just a little more than a second before being raised again.
Further details of the normal construction of the sheets and the associated pinning are to be found in "The Mechanics of Flax Spinning" by Vernon Pringle, published by H. R. Carter Publications Ltd. in 1951.
As previously pointed out, in order to provide an adequate length of working reach for combing the fibres and for raising each bundle of flax above the top of the sheets, the height of the channel in its raised position and hence the overall height of the machine is in the region of eight feet (2.5 metres), and this, in combination with the lengths already referred to, gives a very large, cumbersome machine.
According to the present invention, combing mechanism of the general type just described, that is to say comprising co-operating arrays of pins which are driven around closed paths to form a substantially vertical working reach over which the pins in the arrays are opposed as they move in a downward direction alongside one another in order to comb a bundle of fibres located in the gap between them and means for moving a bundle of fibres into the zone of the working reach also includes mechanism for periodically adjusting the spacing between the co-operating arrays of pins in the working reach so as to increase the gap between them at a time when there are no fibres present. When the bundle of fibres has been moved into the working reach, the pins move together again until they reach their normal operating positions, the combing action thus being started in a gradual and relatively gentle manner which contrasts favourably with the operation of previous constructions of such mechanism where the fibres were engaged abruptly by fully intermeshed pins, leading to an inevitable tearing action. The much gentler effect achieved in accordance with the present invention is found to lead to a marked improvement in the overall quality of the resultant product.
This improvement does not depend on the direction in which the bundle of fibres is introduced into the working reach. Thus the mechanism for raising and lowering each bundle of fibres, as already described, can be retained, while still yielding the improved results just referred to. On the other hand, as mentioned above, previous machines have been very large and cumbersome and while this has been acceptable in the past, a more compact machine is now preferred. The fact that the bundle of fibres is introduced into the working reach at a time when the pins are spaced apart means that it is possible to move the bundle of fibres into position in a lateral direction and thus obviate the need for the raising and lowering mechanism previously described, thereby materially reducing the overall height of the machine and at the same time enabling a faster rate of movement of the bundles of fibres along the machine.
If the traditional form of pin-carrying structure is retained and the arrays of pins are supported by rollers as described above, the movement for periodically adjusting the gap between the two arrays of pins in the working reach is preferably caused by pivoting one or each array about the axis of a main lower supporting roller. The effect of such pivoting movement is that the spacing is greater at the top than the bottom and when the pins are moved together in the operating cycle, combing commences at the lower end of the bundle of fibres and moves progressively upwards. This applies the load gradually until the arrays of pins reach a position in which the opposed faces in the working reach are parallel or subst antially so. This leads to a more intensive hackling than with the conventional arrangement where the gap between the working reaches diverges towards the bottom to leave an appreciable gap between the opposing pins at the lower end in order to ease the strain on the fibres as the bundle is raised and the fibres are pulled through the pins which are moving in the downward direction.
Although it is possible to achieve such a result by the pivoting movement of only one array of pins, the pivoting of both arrays so as to move them by substantially equal distances leads to symmetrical working which is preferable. Whether or not the arrays of pins are pivoted at just described, it is preferred that the co-operating arrays of pins should move by substantially equal distances for this reason.
In order to control the movement of the arrays of pins as they move around their closed paths, a guide roller is preferably located above each lower supporting roller so as to define the lower end of the working reach, so that when the pins are in the position of full engagement the paths of the pins below the working reach diverge. The mechanism for adjusting the spacing between the co-operating pins in the working reach is preferably cam-controlled and it may operate so that the co-operating pins separate more rapidly than they come together.
Now although the co-operating arrays of pins can operate singly, best results are obtained if there are a plurality of co-operating arrays arranged side by side such that a bundle of fibres can be moved progressively in steps in a lateral direction between the co-operating arrays so as to be combed by successive arrays of co-operating pins. As with the traditional type of machine described above, the pinning of the co-operating arrays of pins preferably becomes progressively finer in the direction of movement of the bundle of fibres.
An example of combing mechanism in accordance with the invention in the form of a hackling machine for flax and similar fibres will now be described with reference to Figures 3 to 8 of the accompanying drawings, in which:-

Figures 3 to 6 are diagrammatic end views to an exaggerated scale illustrating successive stages in the cycle of operation;
Figure 7 is a detailed view to an enlarged scale of part of a gripping arrangement for bundles of fibres; and
Figure 8 is a sectional view on the line VIII -VIII in Figure 7.

The apparatus illustrated is designed for the hackling of flax fibres and will be described in this context, as in the original description. The scale of Figures 3 to 6 is exaggerated so as better to illustrate the effect of adjusting the gap between co-operating arrays of pins. In practice this gap will be much less than shown.
Turning first to Figure 3, a bundle of fibres 32 is shown suspended from a holder 34 which is of a modified construction as will be described. A pair of co-operating pinned sheets 31 and 33 (i.e. hackle bars supported by the tie bars spanning endless belts as described with reference to Figures 1 and 2) are illustrated in an open position in which the pins on the sheet are clear of the fibres 32. The sheet 31 passes around a main lower driving roller 37, an upper idler roller 38 and a guide roller 39 which, with the roller 38 defines the working reach. The sheet 33 passes around similar rollers 35,40,41, the rollers 35 and 37 turning in opposite directions so as to drive each sheet downwardly over the working reach, as illustrated by the arrows.
The rollers 38,29 and 40,41 are mounted on respective supporting plates 44 and 45 supported for pivotal movement about the axes of the respective driving rollers 37 and 35. Each assembly is balanced so that the effect of its own weight provides a bias which urges the two assemblies together. The two plates 44 and 45 are controlled by identical cam mechanisms each comprising a driven cam 50 co-operating with a rolle r follower 51 on an arm 52 pivoted at its lower end to a fixed point 53. Each arm 52 is connected at its upper end to the respective plate 44, 45 by a link 54 of adjustable length. Rotation of the cams 50 in the directions shown by the arrows and the biasing of the plates towards each other thus causes the plates 44,45 to rock about their pivots and thus to move the sheets 31,33 through a sequence of positions as illustrated by the successive Figures of the drawings.
As already mentioned, Figure 3 shows the sheets 31,33 in their separated or "open" position in which the flax fibres 32 may readily be moved in a horizontal direction at right angles to the plane of the paper. The fibres lie along the centre line of the gap between the two sheets, so that as the latter gradually come together, they operate symmetrically on the fibres. During the first stage of the movement as illustrated in Figure 4, the pins at the lower end of the working reach move into gradual engagement with the lower end of the bundle of fibres. Thus, in each cycle, hackling commences at the lower end of the bundle and moves progressively upwardly, thus reducing the strain on the fibres as the sheets move from the position of Figure 4 to that of Figure 5 in which the working reaches are substantially parallel and there is full engagement between the pins and fibres for the whole length of the working reach.
The cams 50 turn at a constant speed and, as seen in Figure 5, have a profile which includes a circular arc 60 which engages the respective follower 51 as the sheets 31,33 reach the parallel or closed position of Figure 5, so that there is a dwell in this position, which in a particular example may be of the order of two seconds. After this dwell, the sheets then separate again and the profile of the cams 50 is such as to cause the sheets to separate or open more rapidly than they close. This rapid opening in conjunction with the downward movement of the pins ensures that the flax bundles rapidly clear the pins and do not tend to cling to them. The position of Figure 6 which is identical to that of Figure 3, completes the cycle, and leaves the flax bundle free to be moved horozontally to the next hackling position between a corresponding pair of sheets with a finer set of pins, the cycle then being repeated as just described.
As mentioned above, the holder 34 is of a different construction from those shown in Figures 1 and 2, and is illustrated in detail in Figures 7 and 8. Basically, it comprises a pair of endless belts 65 and 66 which grip the bundles of flax between them as best seen in Figure 8. At the inlet, the belt 66 passes around a guide pulley 68 where it meets the lower belt 65, the two belts then passing together over a further pulley 70. The bundles of flax 32 are fed to the belt at the correct spacing by automatic feed apparatus (not illustrated) and, after passing the pulley 70 travel horizontally between the co-operating arrays of pins, as already described with reference to Figures 3 to 6.
To complete the gripping of the bundles 32, a roller chain 72 with side plates 73 passes around a chain wheel 74 and meets the belts 65 and 66 as they pass over the pulley 70 so that the belts are enclosed by the opposite side plates 73 as best seen in Figure 8. The lower belt 65 rests on a support plate 76 and the bundles of flax 32 are thus held between the belts 65 and 66 in conjunction with the side plates 73, which together provide a wedging action. The belts 65 and 66 and the chain 72 move together intermittently along the length of the machine, coming to a standstill at intervals as the combing operations takes place and then moving on to transfer the respective bundles of flax 32 to the next stage of combing.
Whatever the method of holding the bundles of flax or other fibres, the ability to move each bundle from one group of pins to the next by horizontal movement, obviates the need to lift the holders, whether in the form shown in Figures 1 and 2 or Figures 7 and 8, and thus leads to the possibility of a more compact, faster machine. In addition, as previously mentioned, the pivoting of the sheets leading to the combing process extending progressively up each bundle improves the overall quality of the resultant product, but pivoting movement is not essential and a similar result may be achieved by bodily movement of each sheet in a horizontal direction so that the working reaches remain parallel throughout, or at least substantially so.
While the invention has been described in relation to a hackling machine, it will be understood that it may be applicable to other fibre combing mechanisms comprising co-operating opposed sets of toothed or pinned members, each moving in an endless path to provide a working reach between them through which bundles or slivers of fibres or the like are passed and combed.

Claims

1. Combing mechanism comprising co-operating arrays of pins (31,33) which are driven around closed paths to form a substantially vertical working reach over which the pins in the arrays are opposed as they move in a downward direction alongside one another in order to comb a bundle of fibres (32) located in the gap between them, and means (10,12,14) for moving a bundle of fibres into the zone of the working reach characterised by mechanism (50,51,52) for periodically adjusting the spacing between the co-operating arrays of pins in the working reach so as to increase the gap between them at a time when there are no fibres present.

2. Mechanism according to claim 1 characterised in that the means (65,66) for moving a bundle of fibres operates to move the bundle laterally at a time when the gap is increased.

3. Mechanism according to claim 1 or claim 2 characterised in that the array of pins (31,33) are supported by rollers (37,38,35,42) and the adjusting movement is caused by pivoting one or each array about the axis of a main lower supporting roller (35,37).

4. Mechanism according to any one of the preceding claims characterised in that the mechanism (50,51,52) for adjusting the gap between the co-operating arrays of pins operates to move both arrays of pins by substantially equal distances.

5. Mechanism according to claim 3 or claim 3 together with claim 4, characterised in that a guide roller (39,41) is located above each lower supporting roller (37,35) so as to define the lower end of the working reach so that when the pins are in the position of full engagement, the paths of the pins below the working reach diverge.

6. Mechanism according to any one of the preceding claims, characterised in that the mechanism (50,51,52) for adjusting the gap between the cooperating pins in the working reach is cam-controlled.

7. Mechanism according to any one of the preceding claims, characterised in that the operation of the adjusting mechanism is such that the co-operating pins separate more rapidly than they come together.

8. Mechanism according to any one of the preceding claims characterised in that a plurality of co-operating arrays of pins are arranged side by side such that a bundle of fibres can be moved progressively in steps in a lateral direction between the co-operating arrays of pins so as to be combed by successive arrays of co-operating pins.

9. Mechanism according to claim 8, characterised in that the pinning of the co-operating arrays of pins becomes progressively finer in the direction of movement of the bundle of fibres.

10. Mechanism according to claim 8 or claim 9 characterised by gripping members (65,66) for holding the bundles of fibres (32) and means (70,74) for moving the gripping members in a generally horizontal direction above the co-operating arrays of pins.

11. Mechanism according to claim 10 characterised in that the movement of the gripping members (65,66) is synchronised with the mechanism (50,51,52) for adjusting the gap between the co-operating arrays of pins so that each bundle of fibres (32) is moved from one group of pins to the next when the arrays of pins (32,33) are more spaced apart.

12. Apparatus according to claim 10 or claim 11 characterised in that the gripping members comprise a pair of co-operating opposed belts (65,66) guided in a generally horizontal direction so as to grip the bundles of fibres between them and move the bundles between successive groups of pins.

13. Mechanism according to any one of the preceding claims designed for the hackling of fibres such as flax.

14. A method of combing a bundle of fibres between co-operating opposed arrays of pins which are driven around closed paths to form a substantially vertical working reach over which the pins in the opposed arrays move in a downward direction alongside one another characterised in that the spacing between the opposed arrays of pins in the working reach is periodically adjusted so as to increase the gap between them and the bundle of fibres is moved into the zone of the working reach at a time when the co-operating arrays of pins are more spaced apart.

15. A method according to claim 14 characterised in that the spacing between the arrays of pins is adjusted in such a way that the pins separate more rapidly than they come together.

16. A method according to claim 14 or claim 15 characterised in that the spacing between the arrays of pins is adjusted in such a way that the pins come together first at the bottom of the working reach so that the combing process extends progressively up the bundle of fibres.

17. A method according to any one of claims 14 to 16, characterised in that the bundle of fibres is moved progressively in steps in a lateral direction from one group of co-operating arrays of pins to the next so as to be combed by successive groups of pins of which the pinning becomes progressively finer.

18. A method according to claim 17 characterised in that the bundle of fibres is held by gripping members and is moved in a generally horizontal direction between the cooperating arrays of pins.

19. A method according to claim 18, characterised in that the bundle of fibres is held between a pair of co-operating opposed belts guided in a generally horizontal direction.

20. A method according to any one of claims 14 to 19 characterised in that a plurality of bundles of fibres are combed simultaneously between successive co-operating arrays of pins.