DE1000672B - Device for slitting or cutting cardboard u. Like. For the production of boxes - Google Patents

Description

GERMAN

The invention relates to one for slitting or cutting cardboard and the like for the manufacture of Boxing device, which consists of several of an upper and a lower as well as a main wilt Longitudinally displaceable half-part with an upper and lower cutting element each Contains cutting units, which transversely along threaded spindles running parallel to the main shafts arranged to be movable and adjustable at the same time to the direction of travel of the carton and for operation can be driven in opposite directions with their half-parts around the main shafts.

So that such machines can be used as versatile as possible, the half-parts are theirs Cutting units are usually longitudinally displaceable along a main shaft. With the known Schlitzoder Cutting devices have these adjusting organs or adjustable brackets for the Cutting units, however, have various shortcomings that may be that the movably mounted and the half parts of the cutting units carrying the cutting knife are insufficiently guided and therefore tilt slightly, which means that the knives no longer produce a perfect cut and on the other hand are also conditioned by the fact that not the half-parts themselves, but special ones Knife carriers guided by guide links tilt easily because the guide links are insufficient are rigidly guided on rotatable setting spindles.

Other known devices for slitting or cutting cardboard and the like are extensive and expensive gears are required if these also have the aforementioned disadvantages Devices should be arranged adjustable more than four cutting units.

The invention has for its object to improve the known devices in such a way that the lateral adjustment of the individual cutting units without any disadvantages for the effect of the cutting work is possible and the construction, for. B. also with regard to angular adjustability of the cutting members to each other, but simply fails and the device can be used universally.

The aforementioned object is achieved according to the invention in that each half part of each cutting unit a pair of annular bodies which are concentric to the axis of rotation of the half-part and can be rotated relative to one another contains, wherein the one ring body of the upper half part, the upper cutting element or knife and the corresponding ring body of the lower half part, the lower cutting element or the associated supplementary cutting element carries and in the other ring body of the two half parts of each cutting unit one in Device for slitting or cutting cardboard and the like for production

of boxes

Applicant:

The Deritend Engineering Company
Limited, Birmingham (Great Britain)

Representative: Dipl.-Ing. R. Beetz, patent attorney,
Munich 22, Steinsdorf str. 10

Thomas Desmond Bishop, Birmingham

(Great Britain),
has been named as the inventor

axial direction immovable threaded nut is rotatably mounted on a corresponding Thread one secured against rotation around its own axis and by the same parts all Cutting units through rod sits, and that in addition to the usual drive elements for counter-rotating Rotation of the half-parts assigned to one another, on the one hand, with drive rods provided with toothed rings for similar rotation of the ring body carrying the cutting elements either in the sense of a Advance or lag relative to the other ring bodies of the same cutting unit provided and on the other hand threaded spindles are mounted in drive wheels wedged on the main shaft which the threaded nuts stored in the ring bodies of a particular cutting unit are grooved over Spindles can be rotated together by means of pinions, so as to achieve the same movement and adjusting the two half-parts of each cutting unit transversely to the direction of travel of the cardboard and the like to be achieved by the device.

Details and further embodiments of the invention can be found in the description below, in which an embodiment is explained with reference to the drawing. In the drawing is of the four cutting units of the device only one shown for the sake of clarity, and also from the two pairs of cooperating positive and negative cutting members of each cutting unit only a pair is shown, but the inventive design can also be used in devices with

find more or less cutting units application.

In the drawing represents

Fig. Ι a sectional view of the device accordingly the section line X-X in Fig. 2,

Fig. 2 is an essentially schematic side view one of the cutting units, soft the mutual arrangement of the various shafts in the Relation to the cutting units shows, looking from the right, in the sense of FIG.

3 shows a longitudinal section through the device for the simultaneous relative adjustment of an associated Pair of knives, as it is on each side of each cutting unit, and

Fig. 4 is a view of the device - partially in section - which serves to maintain the mutual adjustment between all the cutting organs of the cutting units and the feeding device.

The gears 11 and ΐΐ _α have eccentrically attached to them _{drive rods 13 and I3 a} (Fig. 2), which are parallel to the adjacent main shafts and 7 _a and through appropriately sized openings in the inner ring bodies 8 and 8 _Ö one pass through each half part of the four cutting units which are arranged on the main shafts 7 and 7 _a . The ends of the driving rods 13 and 13 ,, are _{fastened in a gear 14 or I4 a} on the other side of the rack frame; these two gears mesh with one another and are mounted on the main shafts 7 and y _a , respectively, the gear wheel I4a being indirectly wedged to the main shaft y _a. From this arrangement it follows that every rotary movement which is given to one of the two main drive wheels 14 or 14 "is transmitted to the other two main _{drive wheels 11 or 11 0} and that by means of the driver rods 13 or 13", the inner ring bodies 8 or 8 _{ß of} the cutting units caused

On a base plate, not shown, is a 20, which is in line with its main

Pair of head plates 5 and 6 arranged by not Shown Ouerstänke are anchored together and so form a frame in which the device is housed.

In the two head plates and S 6 are two mutually parallel main shafts 7 and y _a are mounted, the shaft 7 to rotate 7 and y _a perpendicular waves to the shaft y _a. On the inside of the main drive wheels 11 or n _a , ie on the

lies. The four cutting units are slidably mounted on these shafts 7 and y _{a, of which only one}

On the side facing the cutting units, annular ring gears 15 or in the sense of _a are arranged, the outer diameter of which corresponds to _{the outer diameter of the main drive wheels 11 or H 0.} The ring-shaped ring gears are in engagement with one another and are rotatably mounted on cylindrical lugs of the main drive wheels 11 and n _a . The annular tooth is shown. Each of the cutting units comprises two wreaths 15 or i5 _a take in corresponding opening half-parts, which correspond essentially and to the ends of driver rods 16 and i6 _a , of which one is on the upper main shaft 7 and the one by appropriately sized Breakthroughs of the other on the underlying main shaft y ″ in the outer ring bodies 9 and 9 _a, each on which is arranged. Since the two half-parts pass through the same cutting unit seated in essentially the same main shaft, the corresponding individual parts 35 go. The opposite ends of the Mitnehmerderbeiden half parts the same reference numerals, but are bars in associated annular gear rims carry the individual parts of the lower main shaft 7 _a a 17 and i7 _a stored later than the feed drive index 0. Each of the two half-parts has a wheels designated will. They are rotatable on ring ring body 8, 8 _ß , which is rotatably mounted on the associated attachments of the drive wheels 14 and I4 _a and main shaft 7, y _u and which continue to be 40 in engagement with each other. It is evident that the inner ring body is called. A further ring body 9, g _a, forced onto the ring-shaped toothed ring I5 _O , is rotatably mounted on it
will continue to be referred to as the outer ring body.
The two ring bodies 8 and 9 each have a radial

outstanding knife, from which this is transferred to the outer 45.

Rotary movement on the ring-shaped toothed ring 15 and through the driving _{rods 16 or i6 a} on all outer ring bodies 9 or q _{u of} the four cutting units

Ren ring body 9 seated knife is represented by the reference numeral 10. The ring bodies 8 _a and g each carry a cutting element that works together with the knives, of which the cutting element seated on the outer ring body 9 is represented by the reference symbol io ″.

According to the invention, the angular adjustment of a cutting member io "can relative to the other cutting member of a SchneidDie of the apparatus for simultaneous angular displacement of each blade or cutting member pair is in Fig. 2 schematically indicated by A shown in Fig. 3 in detail.

The drive wheel ii _e or the ring-shaped ring gear ^{1 Si / (FIG. 1,} bottom right) are in engagement with a respective gear 18 or 19 (FIG. 3), which have the same diameter. The gear 18 is arranged with a sliding key on a drive shaft 20 such that a Dhb Z

unit at a remote location. Such a rotary movement of the drive shaft 20 to the gear wheel position automatically causes a corresponding angular 18 to be transmitted, but the drive shaft itself is a moderate setting of the associated pair of knives. It
it goes without saying that with such an adjustment the angular adjustment of all knives

and cutting members of the four cutting units equally splines 60 which comprise the drive shaft 20 and a done in good time. has a steep internal thread that with

move in the axial direction with respect to the gear 18 which is itself secured against axial displacement can. The gear 19 is ver with a socket 21

_{On one side of the frame,} gears 11 and II ″ are provided on the main shafts 7 and 7, respectively, which continue to act as the main drive wheels

lih Dh

gg g a

corresponding external thread is engaged on the drive shaft. Usually the two gears 18 and 19 together from one

Ie

are designated. They have the same diameter 65 gear 22 (Fig. 3, left) set in rotation.

and are in engagement with each other. These gears or, ΐΐ _β have socket-like projections 12 and I2 _a , which include the main shafts 7 and y _a and are wedged on them. Their purpose will be explained later.

The latter receives its drive from a power source, not shown, and is also in engagement with the gear wheel I7 _a (Fig. 1, bottom left), so that on the main _{drive wheels n a} and 11 and on the ring-shaped gear rims I5 _ß and 15 the same rotary movement

is transmitted. The drive shaft 20 can be displaced axially by means of a special device. Since the drive shaft 20 is connected to the bushing 21 (Fig. 3) that surrounds it and is secured against axial displacement via a steep thread, such a displacement causes a relative rotation between the two gears 18 and 19 11 or n _a and the

referred to as the first, second, third and fourth adjustment pinions for the lateral adjustment. This Einstellritzel have the same diameter as the main drive wheel 11 and are in engagement with one 5 of the respective four Einstellritzel 32 _a, 33 _beta, 2,4a and 35a 'that of the main drive wheel ii _a sitting on the sleeve-like approach I2 _O. These setting pinions for the lateral setting are on the outer side of the main drive wheels 11, ii _a , i.e. opposite to

rmgfövmigen gear rims 15 or 15 _a brought about 10 set to the previously mentioned ring-shaped tooth and thereby in turn a relative rotation wreath 15, i5 _a . The adjusting pinions 32, 33, 34 and 35 between the main _{drive wheels 11 or n a} and the timing adjustment all have internal gearing, outer ring bodies 9 or g _{a of} each cutting unit, each with one of four gears 36 (of which in so that the mutual angular adjustment of each of the drawings can only be seen one) are engaged in the pair of knives and each pair of cutting members 15, one of which goes on one of four lengthways at the same time and in a coincident manner. spindles 37 is arranged. These longitudinal spindles 37. The axial displacement of the drive shaft 20 goes through the main pinion 11 and each of the following: inner ring body 8 of the half-parts of the cutting-An externally threaded bushing units that are united with the main shaft 7, 23 is on a stepped part of the drive shaft 20 therethrough. They are rotatably mounted with their ends in the drive wheel 20 and carries handles 24 (FIG. 3), 14 mounted.

with the help of which it can be rotated. Although in a similar way each of the adjusting pinions 32 _a ,

this bush 23 about the drive shaft 20 freely rotatable 33 _a , 34 _a and 35 _a an internal toothing, which is with one, so it is opposite her by low-friction of four gears 3O ₀ (of which in the drawing thrust bearings 25 and 26 on one Axial displacement 25 can only be seen one) is engaged. One of these hindered each. The external thread of the bushing 23 engages the adjusting pinion is on one of four longitudinal spindles 37 _a in the internal thread of a bushing 27 which is arranged with the _{one that is firmly connected to the main drive wheel n a} and each head plate 6 of the rack frame. the inner ring body 8 _{a of} the half-parts of the cutting-From this it follows that when the bushing 23 is rotated units which are "united with the main shaft 7" penetrate the bushing 23 together 30 with the aid of the handle 24. The ends of the spindles 37 _a are in

is displaced with the drive shaft 20 in the axial direction with respect to the frame of the device and also with respect to the socket 21 secured against axial displacement in the frame. The drive shaft 20 is rotated in the process.

A lock nut 28 is provided with a handle 29, so that the socket 23 in the particular desired Location can be determined.

So that each cutting unit is perpendicular to the infeed

the drive wheel I4 _ß stored.

Since the longitudinal spindles 37 or 37 _a and the adjusting pinions 32 to 35 or 32 _a to 35 _a , which are connected to the main shafts 7 and 7 _a , are the same. 35 so the following description deals only with the mechanism connected to the main shaft 7, because it is clear that the _{mechanism connected to the main shaft 7 a is} in gear connection with the former, whereby a precise

Device od the cardboard. Like. Can be moved, 40 corresponding movement of the with the main shaft y _a

According to the invention, the adjustment drive is designed in such a way that the half-parts of the cutting

det that each cutting unit gives independent of the units. Each of the adjusting pinions 32, 33, 34

other cutting units to move. and 35 for the side adjustment stands over_ his

With each of the main drive wheels 11 or n _a internal toothing in engagement with only one of the four

are the ends of three threaded 45 longitudinal spindles 37, and each of these longitudinal spindles 37

and at equal intervals all around on the main stands with the threaded nuts 31 of one half-part

drive wheels arranged rods 30 or 3O "eccentric" only a single cutting unit in gear connection

trically connected. They lie parallel to the main dung. However, the following description applies to

waves 7 and j _a and are on the opposite side in the same way for each adjusting pinion for the side

Frame in the drive wheels 14 or i4 _a ge 50 setting and the associated longitudinal spindle,

stored and wedged with them so that they are not around. Each longitudinal spindle 37 has a longitudinal groove 38 and goes

can rotate their own longitudinal axis. The three threaded rods 30 each penetrate the inner ring body 8 arranged around the main shaft 7

through the inner ring body 8 of each half part of the four arranged on the main shaft Cutting units. But only in one of these

upper half parts of all cutting units, and each 55 inner ring body 8 engages them in a pinion 39, of them is in engagement with one of three with the non-rotatable but axially internal thread provided on the longitudinal spindle 37 nuts 31, which are in the
inner ring bodies 8 are located. The three threads

bars 3O _a penetrate the inner ones in the same way

is arranged displaceably. This pinion 39, which is arranged in the inner ring body 8, drives a toothed ring 40 which is rotatably mounted on an attachment of the inner ring ring body 8 _{a of} the 60 body 8 arranged around the main shaft 7 _a and, in turn, with three pinions lower half parts of all cutting units, and each 41 is in engagement, which is in engagement with the on the three Gevon them with one of three with threaded rods 30 seated three threaded nuts 31 internally threaded nuts 3I ₀ , which are in one piece. It follows from this that inner ring bodies are 8 ″. The threaded nuts of each longitudinal spindle 37 and their corresponding longitudinal 31 and 3i _a are rotatably mounted in the corresponding inner ring spindle 37 _a only one of the four cutting units, but they can be counteracted.

do not carry out any axial displacement. Those with the main shaft 7 in connection

On the socket-like extension 12 of the main longitudinal spindles 37 are at one end (Fig. 1,

drive wheels 11 are four additional ring-shaped right) provided with claws 42 on which a removable

Ring gears 32, 33, 34 and 35 arranged, later 70 face crank can be attached. Should at-

For example, the first unit (that is the unit shown in the drawing) receives a lateral displacement relative to the direction of travel of the cardboard by the device, the hand crank is attached to the longitudinal spindle 37 and the spindle is rotated accordingly. The rotation of this longitudinal spindle 37 causes a rotation of the pinion 39 coupled to it in the associated half part of the first cutting unit. The three threaded nuts 31 in this half-part of the first cutting unit, which sit on the three non-rotatably mounted threaded rods 30, are rotated via the pinion 40. As a result, this half part of the first cutting unit is axially displaced along the main shaft 7. Due to the fact that the pinion 36 seated on the longitudinal spindle 37 is in engagement with the first adjustment pinion 32 for lateral displacement and that this adjustment pinion 32 in turn meshes with the first adjustment pinion 32 _a for lateral adjustment and that this first adjustment _{pinion 32 a} If in turn (via its internal teeth) is _{in engagement with a pinion 36 seated on the corresponding longitudinal spindle 37 O} belonging to the other main shaft J _a , the longitudinal spindle 37 _a receives a completely corresponding rotary movement. The latter causes an identical and corresponding axial displacement of the other half-part of the first cutting unit in exactly the same way. There are therefore means by which the two half-parts of a specific cutting unit can be adjusted simultaneously and coincidentally in the axial direction on the main shafts 7 or y _a.

The conveyor mechanism (for the box) connected to the device is activated by a non-circular disk 43 (FIG. 1, bottom left). The latter is connected to a gear 44 which is driven by the drive wheel i4 _a . Means are provided to enable a relative rotation between the two gears i4 _ß and 44. These means are indicated schematically by the reference character B in FIG. 2, while they are shown in detail in FIG. These means consist of a gear 45 which _{meshes with the drive wheel I4 a} and which engages in a keyway 46 of the shaft 47 on which it is mounted. In this way, a rotary movement of the gear 45 is transmitted to the shaft, but the shaft 47 can move axially in the gear 45, which is secured against axial movement. The shaft 47 has a part which is provided with a steep thread 48 which engages in a corresponding thread inside a bushing which is secured against axial displacement. A toothed wheel 50, which is in mesh with the toothed wheel 44, is seated on this bushing 49.

As can be seen, causes an axial displacement of the W ^T elle 47 and provides a relative rotation between the gears 45 and 50 indicate a result of which a relative rotation between the drive wheels I4 _a 44th Thus, the temporal work of the conveyor device for the carton can be brought into a desired relationship with the temporal work of the cutting elements of the device.

The means for axially displacing the shaft 47 are not shown individually. You correspond but exactly the device shown in Fig. 3 for the axial displacement of the shaft 20. The handles 51 correspond to the handles 24 and the handle 52 corresponds to the handle 29.

The ends of the longitudinal spindles 37, which are provided with claws and grasped with a crank handle have keyed, toothed ratchet wheels 53 into which spring-loaded ratchets are usually used intervene and thus prevent these longitudinal spindles 37 from rotating. These pawls have a curved profile, causing the pawl to automatically disengage from the toothed ratchet 53 comes when the crank handle is attached to the longitudinal spindle.

Claims (5)

Patent claims: i. For slitting or cutting of cardboard and the like. For the production of boxes serving device, which contains several cutting units consisting of an upper and a lower as well as longitudinally displaceable on a main shaft with an upper and lower cutting element each, which along parallel to the main shafts running threaded spindles transversely to the direction of movement of the cardboard at the same time movable and adjustable and can be driven for operation with their half parts around the main shafts in opposite directions, characterized in that each half part of each cutting unit has a pair of annular bodies concentric to the axis of rotation of the half part and rotatable relative to one another (8, 9 or S ₈ , g _a ) , the one ring body (9) of the upper half part the upper cutting element or knife (10) and the corresponding ring body (g _a ) of the lower half part the lower cutting element or associated supplementary cutting element (io _a ) and in the other ring g body (8 or 8 _a ) of the two half parts of each cutting unit an axially immovable threaded nut (31 or 3i _ß ) is rotatably mounted, which is secured against rotation about its own axis on a corresponding thread of one and through the same parts of all cutting units passing rod (30 or 30 ") sits, and that in addition to the usual drive elements for counter-rotating the half-parts associated with each other on the one hand with toothed rings (15, 15") provided driver rods (16, i6 ") for the same type of rotation of the ring body carrying the cutting elements (9 or 9 _a ) either in the sense of a lead or a lag relative to the other ring bodies (8 or 8 ″) of the same cutting unit and on the other hand in drive wheels (11 or ii ) wedged on the main shaft (7 or y _{a) a} and 14 or 14J threaded spindles (30 or 30 _a ) are mounted on which the threads mounted in the ring bodies (8 or 8 _a ) of a certain cutting unit nuts (31 or 3i _a ) can be rotated together using grooved spindles (37 or 37J by means of pinions (39, 39 ", 40, 40" and 41, 41 ",) so that the movement and setting of both To reach half parts of each cutting unit transversely to the direction of the cardboard and the like. 2. Apparatus according to claim 1, characterized in that a main shaft (7 or 7 _a ) associated longitudinal spindles (37 or 37 _a ) z. B. are individually and independently rotatable by means of a crank on the spindle in question, the rotation of the spindle (37) via the pinion (36), the internally toothed wheels (32, 32 _a ) and the pinion (36 _a ) on the Spindle (37J is transferred. 3. Device according to claim 1 or 2, characterized in that a regulating device (24, 20, 21, 18, 19) is provided _{for the relative rotation of the cutting members (10 or 10 a) of a cutting unit, which rotates the gear rims (} 15, 17 or 15 ″, _{ιγ α} ) compared to the associated main drive wheels (11, 14 or ii _a i4 _a ) allows during operation of the device. 4. Device according to claims 1 to 3, characterized by a control device (51, 47, 49, 50, 45), the temporal work of the Conveyor (43) for the carton during operation in an intended relationship with the Can adjust temporal work of the cutting organs of the cutting units. 5. Device according to claims 3 and 4, characterized in that at least one of the control devices (24, 20, 21, 18, 19 or 51, 47, 49, 50, 45) from an optionally at the same time serving to drive the cutting units shaft (20 or 47), which are next to each other on the one hand with a longitudinal groove (46) and on the other hand with a steep thread (48) and is also mounted so as to be longitudinally displaceable, both on the longitudinal groove (46) and on the part of the shaft (20 or 47) containing the steep thread (48) ) a gear wheel (18, 19 or 45, 50) in corresponding engagement with the longitudinal groove or the steep thread, but otherwise immovable in the axial direction, of which one (18 or 45) with a main drive wheel (n _a or 14J and the other (19 or 50) with a toothed ring (i5 _a ) or with a gear (44) serving to drive the conveyor (43) meshes, and the respective control by a corresponding longitudinal displacement of the Wave (20 or 47) takes place. Considered publications:
German Patent Nos. 371 837, 483 107;
U.S. Patent Nos. 1,977,812, 2,117,220. 1 sheet of drawings © 609 740/57 12.56