The invention relates to an individualization station for separating items. Such an individualization station is used in a goods processing system, such as a station of a mail processing route of a franking system.
The mail processing route of a franking system is typically composed of a number of mail piece processing stations arranged individually in series. A placement station is set up upstream in terms of the mail flow from the individualization station, i.e. often at the start of the mail route, and serves for the placement of individual or stacked mail pieces at the individualization station, which individualizes the stack. If the stack contains mail pieces with different formats (mixed mail), high requirements for individualization must be satisfied. The individualized mail pieces are supplied directly or via a dynamic scale to a franking machine, and then are stored in a tray station.
The standard “Letter” format is to be processed in America, such as Letter 8½ inch×11 inch (21.59 cm×27.94 cm), Letter 8½ inch×14 inch (21.59 cm×35.56 cm), Letter 14⅞ inch×11.69 inch (37.8 cm×29.69 cm).
In particular in Germany, the formats B4 (25.0 cm×35.3 cm), B5 (17.6 cm×25.0 cm), B6 (12.5 cm×17.6 cm) and C4 (22.9 cm×32.4 cm), C5 (16.2 cm×22.9 cm), C6 (11.4 cm×16.2 cm) are typical. The sizes of the German paper formats were already established in the year 1922 by the German Institute for Standardization (DIN) in the DIN standard DIN 476.
In the following discussion, a stack refers to a letter stack, postcard stack or other mail piece stacks that can be individualized, but a different stacked flat goods should not be precluded.
Devices for transporting the mail pieces, as well as to loosen the mail pieces (open or closed filled letter envelopes) of a stack so that they can slide more easily over one another, are known, both downstream and in the direction of an alignment wall. Moreover, multiple inclinations of the mail stack plate in the stack magazine region have been proposed in order to use the force of gravity to align the mail pieces. Multiple inclinations of the mail stack plate in the stack magazine region may be present, which may cause the letter envelope to be horizontally pinched, which can also occur in the transition into the supply region, in particular given an opened envelope flap. An alignment of the mail pieces is only possible to a limited degree due to the small angle range.
According to EP 1 533 260 B1, a vibration device is proposed for supplying mail pieces (letters) to an individualization station. Along the entire width of the sluice of the aforementioned individualization station, there is an outer bar having a movable slide rail, at the end of which is a vibratory driving flap. After the placement of a stack with letters lying on their sides, the letters are slid in the longitudinal direction against an alignment wall, by means of the vibratory driving flap, and are thereby loosened by the vibratory driving flap, and thus are aligned, i.e. brought into the correct position before a subsequent individualization and printing. The vibratory driving flap forms a laterally displaceable stop having a slideway that must be adjusted to the letter width and, in this position, can be stopped by means of a friction brake. The vibratory driving flap acts directly on the lateral positioning of mail pieces. In addition, a second slideway is also provided that enables an elastic tolerance by means of a spring, in order to not pinch the letters. However, only letters of the same format can be aligned with this device.
According to EP 1 958 902 B1, a supply device is equipped with an improved transport device that has a number of entrainment means that are formed as a cylindrical wheel having teeth on its circumference in the manner of a gearwheel. Between the teeth are axles for small, undriven rollers that can rotate independently. An alignment takes place when a mail piece or stack of mail pieces is manually slid onto an alignment wall.
EP 1 510 480 B1 B1 discloses an alignment device of a mail processing system that has vibration and alignment devices having a number of retractable elements that protrude through openings of a horizontal plate; the distance thereof from an alignment wall (reference wall) can be adjusted according to the format of the mail pieces in order to restrain the mail pieces, which contributes to preventing an inclination of the mail pieces.
In the aforementioned European patents EP 1 533 260 B1, EP 1 958 902 B1 and EP 1 510 480 B1, the functions of the placement station and individualization station are combined into a single supply and printing station. The correct alignment of the mail pieces is realized by various sliding elements and vibratory driving elements.
These goods processing apparatuses are very loud in operation, and also are prone to failure in the processing of a stack of mail pieces. While the alignment of individual mail pieces is unproblematic, problems may occur in the alignment of a stack of mail pieces of the same format in the event that mail pieces exhibit format deviations. Greater problems occur in the alignment of a stack of mixed mail that contains non-uniform mail pieces of different thickness.
In the field of franking machines, it is known to transport a mail piece individualized from a stack downstream in the transport direction, in terms of the mail flow, and to print that mail piece with a franking imprint during the transport. In the commercially available Centormail® franking machine, mixed mail is transported standing on edge by a transport belt, wherein an alignment of the mail pieces on the edge automatically takes place by gravity. An automatic supply station redesigned in the year 2009 is in the Centormail franking machine. Sliding levers that have a different length, installed on an individualization shaft, are adjacent in the individualization region. These sliding levers are coupled with a reset means. It is advantageous that the letters may be up to 20 mm thick, but nevertheless an optimal takeoff behavior from a stack of mail pieces is possible via the automatic supply station.
In the field of franking machines, solutions are also known that transport a mail piece lying on its side downstream in the transport direction, in terms of the flow of mail, for example the commercially available PostBase® franking machine. This franking machine may be preceded at the input side, in terms of the mail flow by an automatic supply station. For flat goods transported lying on one side, a supply station is known from German utility model DE 20 2012 011 877 U1 that has a contact pressure box having two contact pressure drums that interact with two transport drums borne so as to be rotatable in a frame in order to transport a flat good farther downstream in terms of the flow of goods. In a half of the box that is downstream in terms of the flow of goods, the contact pressure box carries a linkage that is supported at one end so as to be rotatable around a rotation axle shaft, and at the other end, upstream in terms of the flow of goods, carries an approach plate to which are attached individualization fingers that interact with a second individualization drum. The individualization gap is disadvantageously shifted in the transport direction the farther that the sluice opens. A pre-individualization plate is installed on the frame, opposite the supply deck, and with this forms an unchanging gap of a pre-sluice. Since the gap cannot be enlarged, a jam at the pre-individualization plate can be remedied only with difficulty. The franking system formed in such a manner is also suitable only for uniform items of mail.
A device for selecting mail articles, having multiple rotatable fingers, is known from European patent EP 2 325 120 B1. At least two adjacent selectors that can pivot independently of one another have fingers of differing lengths, wherein each of the selector fingers can pivot around a common pivot axis and counter to a respectively associated elastic reset means. That advantageously allows double feeds of mail items (letter envelopes) to be avoided.
European patent EP 2 325 808 B1 discloses an individualization device that, in the upper part of a sluice, is equipped with a number of selection levers curved in an involute shape, which selection levers interact with a selection roller in the lower part of the sluice. Multiple selection levers are arranged next to one another on a rod whose axle forms the rotation axle of the selection lever. The involute of a circle for each selection lever has a vertical segment. Each selection lever is reset separately with elastic force, wherein at least one of the selection levers arrives in contact with the mail piece in a region that extends from the center line of the mail piece, parallel to an alignment wall, up to a parallel edge of the mail piece that is farthest distant from the alignment wall. A first selection lever is positioned at a first distance of 60-85 mm from the alignment wall; a second selection lever is positioned at a second distance of 120-150 mm from the alignment wall; and a third selection lever is positioned at a third distance of 180-230 mm from the alignment wall. The selection levers may only be moved independently of one another. Given a B4 DIN format, the mail pieces are 25 cm wide and 35.3 cm long. A format deviation may case interruptions in operation. A mail piece that is only ⅔ as wide would be 16.67 cm wide, and thus would be smaller in width than the B5 DIN format (17.6 cm×25 cm). The aforementioned smallest distance 180 mm for the third selection lever would still be too large, and would have the effect that the mail piece of ⅔ the width of the B4 DIN format cannot be pressed onto the selection roller by the third selection lever in the lower part of the sluice. Given a format deviation by plus 2 cm from the largest US “Letter” standard format of 8½ inch×11 inch (21.59 cm×27.94 cm), a third selection lever at a third distance of 230 mm from the alignment wall would still be effective, and press the mail piece of B4 DIN format onto the selection roller in the lower part of the sluice. Given a slightly positive deviation from the US format, disruptions may result if, for example, the edge of a 22 cm-wide format does not reach the third selection lever and presses up against an elastic force, or even is situated right next to this and causes an unwanted friction.
Given a stack of at least two mail pieces having a format deviation, and/or given an incorrectly aligned skewed stack, the mail piece lying above might overhang, in particular if the lowermost mail piece is thicker and is smaller in format, for example if the lowermost mail piece has the B5 DIN format and the upper mail piece has the B4 DIN format. For example, the second selection lever would press the upper and the lowermost mail piece of the B5 DIN format onto the selection rollers, and the third selection lever would press only the upper mail piece of the B4 DIN format onto the selection rollers, which selection rollers would draw the two mail pieces simultaneously into the gap of the sluice.
In practice, format deviations also occur in mail pieces, which may lead to unwanted disruption of the operation. For the sake of reliability, a stack of mail pieces is then manually aligned on one edge of the stack, and only then is said stack manually placed at the individualization station.
As used herein, “mixed mail” means flat, predominantly uniform mail pieces of a stack that are of different thickness, which must be processed by the mail processing stations in spite of a tolerance of up to +/−20 mm of the dimensions.
An object of the invention is to provide an individualization station for both a single flat good as well as a stack of flat goods, and for its supply of the individualized good to a subsequent station. The individualization station should enables a high throughput of flat goods that are transported lying on their sides, without the aforementioned disadvantages that occur in the prior art.
Moreover, a jam of larger standard formats should be simple to remedy. The flat goods within a stack should be permitted to have different dimensions (thickness up to 10 mm and format deviations). However, the individualization station should also be suitable for a different stackable good which, in a placed stack, has format deviations of up to 20 mm in length and width. The flat good should rest with the long side on an alignment wall arranged upstream in terms of the flow of goods, and should be drawn, aligned, into the individualization station before it is passed individualized to the following stations.
The individualization station according to the invention has a first sluice region having a first drum of an individualization region in the lower part of the sluice. At least one individualization roller is provided at the first drum of the individualization region. Each individualization roller has a roller body that is jacketed with a rubber or plastic layer. Also a number of individualization rollers with jackets of rubber or plastic, or of a different material having a high coefficient of friction, that each penetrate in a z-direction of a Cartesian coordinate system through an associated opening in a supply deck of the individualization station, wherein the z-direction is opposite the direction of gravity. It is provided that a pivotally supported linkage is extended at its upstream end in terms of the flow of goods, and that an end of an individualization assembly carrier is installed at the linkage end, such that a stop side of the undeflected individualization assembly carrier is aligned parallel to the y/z-plane of the Cartesian coordinate system and extends counter to the y-direction. In a plan view of the y/x-plane of the Cartesian coordinate system at the input side, in terms of the flow of goods, the linkage and the individualization assembly carrier from an L-shape in the upper sluice part.
A number of individualization fingers are provided on the individualization assembly carrier, opposite the first drum of the individualization region. The individualization fingers are respectively laterally associated in pairs with the jacketed individualization rollers. These elements interact so that a lowermost good is individualized from the stack and transported downstream. The individualization assembly carrier has a torsion-resistant profile and has a vertical stop wall upstream in terms of the flow of goods, at which the stack of flat goods is stopped, and an approach plate that forms an inclined introduction region in the sluice. The individualization fingers are installed on the inclined approach plate of the individualization assembly carrier.
The individualization assembly carrier is attached to the linkage, which is supported so as to be rotatable at its downstream end in terms of the flow of goods. Upon individualization, the individualization assembly carrier with the individualization fingers lifts off of the individualization rollers by an amount corresponding to the thickness of the good, counter to the force of gravity, so the individualization assembly carrier is raised to a distance above the supply deck that is variable dependent on the thickness of the flat good. The distance between the sluice and the rotation point is increased by an extension arm of the linkage by an amount that, in the individualization of flat goods of up to 10 mm, the individualization gap shifts only insignificantly in the transport direction x when the sluice opens. A jam of larger standard formats can advantageously be remedied simply via the L-shaped arrangement of the linkage and the individualization assembly carrier, because this structural arrangement allows the good to be manually grasped after a boom and is moved of the individualization gap, for which purpose the supply deck has a reduced width downstream, after the boom of the individualization station. The boom covers the individualization assembly carrier from above, in a u-shape.
A second sluice region is situated next to the first sluice region, counter to the y-direction, and has at least one separate individualization roller in the lower sluice part. This at least one separate individualization roller is at a distance c, transverse to the transport direction x, and in a line to the first sluice region, from a vertical alignment wall of the individualization station. The distance c corresponds to approximately ⅔ to ⅘, preferably ¾, of the width of a flat good of the largest format, with a format deviation of +/−20 mm. The at least one separate individualization roller is connected positively or non-positively with the first drum of the individualization region. The first drum of the individualization region in the first sluice region and at least one separate individualization roller in the second sluice region are preferably driven via a common rotation axle shaft. In the upper sluice part, a rigid mechanical connection is established between the first and second sluice regions by the individualization assembly carrier. A gap is formed in the individualization assembly in the region between the two sluice regions. A flat good to be individualized, which has a corresponding format width, passes through both sluice regions simultaneously due to traction. The individualization assembly of the second sluice region moves to the same degree that the individualization assembly of the first sluice region moves in the z-direction. It has been empirically determined that the risk of an additional flat good (mail piece) being pressed onto the first (or other) individualization roller is advantageously reduced. If that occurred, it may lead to duplicate or repeated intake of mail pieces into the gap of the sluice. Alternatively, a wide, single sluice having a gap in the individualization assembly may also be provided. With a wide sluice having two sluice regions or two rigidly coupled sluices (with an individualization assembly opposite a number of individualization rollers on a rotation axle shaft), a stack is held stable upon drawing the respective lowermost flat good into a removal position, by thereby preventing a tilting of the following additional flat goods (mail pieces) during the removal of the respective lowermost flat good (mail piece) of a stack. This advantage is achieved without using vibration elements and/or additional means.
In an embodiment, the extension are serves not only to extend the linkage, but also serves to allow adjustment. For this purpose, the extension arm is formed of a plate bent in a box-shape, with two lateral sides and a yoke at which two spacer domes of a retention plate are installed. In an intervening space between the extension arm and the two spacer domes, a carrier plate for linkage guidance is arranged, with which an adjustment is achieved.
For example, a precise guidance of the linkage in the z-direction is achieved by a guideway that is molded to the retention plate of the individualization assembly carrier, and with two ball bearings that are respectively arranged on a rod on the carrier plate for linkage guidance. The carrier plate for linkage guidance is displaceable in the y-direction and supported on a stationary axle and, with an adjusting nut, enables precise adjustment of the individualization fingers to the at least one individualization roller (roller body) of the first drum of the individualization region in the first sluice region, as well as of the at least one separate individualization roller (roller body) in the second sluice region. Two double-sided bends of the carrier plate for linkage guidance point in the transport direction x and have openings for a stationary axle that is attached to a carrier angle plate. At least two contact pressure fingers are installed next to one another on the axle so as to be rotatable, with the contact pressure fingers preferably designed to be of identical length. The second drum in the individualization region and the contact pressure fingers interact in order to hold down the flat goods and transport them farther.
An adjustment assembly is supported on the stationary axle and allows the individualization fingers to have an overlap at the at least one individualization roller of the first drum in the individualization region, and allows at least one separate individualization roller to be adjusted. Two attachment elements of the individualization assembly carrier are anchored in the retention plate in order to set a parallel alignment of a short edge of all individualization fingers relative to the supply deck.
The individualization assembly carrier is installed on the surface of the mechanical retention plate that is situated at the input side, in terms of the flow of goods. The individualization assembly carrier has an approach plate that is bent downwardly at an oblique angle in the direction of gravity, and in the transport direction x, from a stop side of the approach plate that is situated parallel to the y/z-plane, upstream in terms of the flow of goods. Attached to the approach plate is the individualization assembly that interacts with the at least one individualization roller of a first drum of the individualization region in the first sluice region, and with a separate individualization region in the second sluice region in order to open the sluice corresponding to the thickness of the respective lowermost mail piece. In the transport direction x, first and second drums in the transport region follow the first and second drums in the individualization region. All drums are rotatable mounted in a frame below a supply deck and are provided with an integrated freewheel mechanism. A rear frame wall extends in the z-direction behind the rear side of a vertical alignment wall for flat goods. The carrier angle plate is attached to the rear frame wall and bent in the y-direction. The individualization assembly carrier installed on the retention plate is arranged with its installation point near to the vertical alignment wall of the individualization station, and has a width that corresponds to the width of the largest possible format of the flat goods, and is bent in the transport direction x at its outlying end opposite the y-direction. The at least one individualization roller of the first drum of the individualization region is at a distance a from a vertical alignment wall, and is situated precisely in the middle of the first sluice region. The smallest format determines the width of the first sluice region, and thus also the distance a at which a flat good with a smallest possible format is still reliably individualized. Additional individualization rollers may be arranged symmetrically on both sides of the at least one individualization roller. The running surface of a covering layer that is installed on each roller carrier may then advantageously be kept narrow so as to be only a strip. The covering layer may be rubber or of a different artificial material having a high coefficient of friction.
In an alternative embodiment, the at least one individualization roller has the width of the first sluice region.
In an embodiment, at least one first individualization roller of the first drum is situated opposite to, and offset in the y-direction from, the individualization assembly in order to form a first sluice region; that an additional, separate individualization roller is situated opposite and offset in the y-direction from another part of individualization assembly in order to form a second sluice region. An additional separate individualization roller of the second sluice region is situated transverse to the transport direction, and parallel to the first sluice region, at a farthest distance c from the vertical alignment wall of the individualization station, such that a gap in the individualization assembly is formed between the two sluice regions. A flat good to be individualized passes simultaneously through two sluice regions by traction, and that the individualization assembly, as noted, has a number of individualization fingers that are installed on the approach plate of the individualization assembly carrier.
An individualization finger that is positioned at a maximum distance from the alignment wall, counter to the y-direction, lifts itself from the rubber surface of the adjacent roller body to the extent that the entire upper sluice part is also moved with the individualization assembly carrier in the z-direction.
It has been empirically found that the risk is reduced of a mail piece being pressed onto the at least one individualization roller drum of the individualization region in the first sluice region while an additional mail piece is pressed into the separate individualization roller in the second sluice region, which may lead to duplicate or multiple intake of mail pieces at the same time into the sluice.
It also has been empirically found that, upon removing the respective lowermost flat good, a stack may be stably held in a removal position by two rigidly coupled parallel sluice regions or a wide sluice, which prevents a tilting of the following additional flat goods (mail pieces) during the removal of the respective lowermost flat good (mail piece) of a stack. This advantage is achieved without using vibration elements and/or additional means. The supply deck may be executed as one part or two parts, and extends from the start of a transport path for the flat good into the individualization region, and extends to the end of the transport region of the individualization station. In the two-part design, the first part and the second part together have the same width as the placement deck of a placement station.
A housing wall of the boom 28 that is directed upstream, in terms of the flow of goods, forms a stack stop wall 281. The boom 28 is firmly connected with the front half 291 of the upper housing shell 29, wherein the front half 291 is installed on a contact pressure box 26 (
The first drum 23a of the individualization region is comprised (the manner is not shown) of a structured drum body having integrated freewheel mechanism, whose structures having the greatest diameter form roller bodies 231a, 232a and 233a on which respective rubber layers are installed. The first drum 23a of the individualization region runs (in a manner shown in
The jacketed first, second and third roller bodies 231a, 232a, 233a are each flanked on both sides by in total four individualization fingers that are installed on the approach plate 265, which is explained in detail in the following using
A fourth roller body 234a passes in the z-direction through an additional opening 204 in the first part 221 of the supply deck at a second distance b from the vertical alignment wall 21, counter to the y-direction. This fourth roller body 234a is also equipped with a separate drum body (not shown) that is equipped with an integrated freewheel mechanism and runs on the driven rotation axle shaft 230a. However, this fourth roller body is not flanked on both sides by individualization fingers, nor is a different individualization assembly situated opposite the fourth roller body 234a. Rather, a gap of length f (
Alternatively, the first drum 23a of the individualization region may be executed with lengthened design so that no separate roller body needs to be installed on the rotation axle shaft. Only one is then required, and the cost of a freewheel mechanism may thus be minimized.
First, second and third roller bodies 231b (not visible), 232b and 233b of the second drum 23b (
In the transport path, a first transport drum 24 follows the second drum 23b in the transport region, wherein the first transport drum 24 is situated opposite a first contact pressure drum 261. In the transport path, a second transport drum 25 that is situated opposite a second contact pressure drum 262 follows in the transport region. The two contact pressure drums are installed spring-loaded and rotatable in a contact pressure box 26 that, near the middle of its front wall, has an opening for a rotation axle 260 a linkage 264. Upon operation of a button 263 installed at the contact pressure box 26, the contact pressure box 26 is moved via elastic force in the z-direction along a guide rod 276, which likewise is described in German utility model DE 20 2012 011 877 U1.
The difference is that, first, instead of the second drum (as in DE 20 2012 011 877 U1) the first drum 23a is now situated opposite in the individualization region, due to an extension of the lever arm length of the linkage by approximately 20%-40% of an individualization assembly carrier 267 with individualization fingers. The individualization fingers installed on the individualization assembly carrier press a flat good to be individualized more strongly against the first drum 23a due to the lever principle and the force of gravity. The static friction is thereby increased and the traction is improved. Second, the width of the individualization assembly carrier 267 in the y-direction is increased to approximately ⅔ to ⅘, preferably ¾ of the largest mail format B4, and now approximates the width W, which reduces the probability of an oblique or duplicate intake of such flat goods that in particular have a large format. Third, contact pressure fingers 2681, 2682 (
The extension arm 2641 of the linkage 264 has a front-side lateral leg 26411 and a rear-side lateral leg 26412 offset in the y-direction, which lateral legs are connected with one another by a yoke 26413 arranged upstream in terms of the flow of goods. The yoke 26413 of the extension arm 2641 is preferably situated at a distance from the linkage end that is situated opposite the other linkage end with the rotation axle 260, wherein the distance is large enough that the distance up to the first drum 23a is bridged. The distance from the rotation axle 260 is thereby further increased in that a retention plate 2642 has two spacer domes 2644, 2645 that are attached to the yoke 26413 and further increase the distance of an installation plate 2673 of the individualization assembly carrier 267 from the yoke of the extension arm 2641. The individualization assembly carrier 267 has a stop side 2671 situated parallel to the y/z-plane, upstream in terms of the flow of goods. A stack stop wall of the boom 28 that is directed upstream in terms of the flow of goods stops a first subset of the stack of flat goods and drops in a step to the stop side 2671 (
The installation plate 2673 of the individualization assembly carrier 267 is bent in the z-direction from the end of the bend 2672. An additional bend 2674 from the stop side 2671 of the individualization assembly carrier 267 in the transport direction is provided at the front-side end of the individualization assembly carrier 267 for a lateral protection of the individualization fingers, and in order to preclude risk of injury to a person who operates the individualization station. The frame 27 has a rear wall 272 at which a carrier angle plate 2751 is installed. A tappet pin 26414 at the extension arm 2641 is situated close to the linkage 264 at the contact pressure box if no flat good is located in the individualization gap.
Alternatively, the individualization fingers are installed on the approach plate 265 together with a respective leaf spring designed as an elastic finger, by at least one installation plate.
A carrier angle plate 2751 (partially visible) is installed on the rear frame wall 272. The carrier angle plate bears a stationary axle 2680 on which is arranged a carrier plate 269 for linkage guidance, which carrier plate 269 can be displaced transversal to the transport direction. A tab 2695 (
The carrier plate 269 has in the transport direction x a bend 2691 (occluded) and a bend 2692 with respectively an opening 26910 (occluded) and 26920. To adjust the individualization finger position transversal to the transport direction x, an adjustment means engages with the stationary axle 2680. The stationary axle 2680 installed in the carrier angle plate 2751 protrudes through the openings 26910 (occluded) and 26920. At the front-side end, a stationary axle 2680 has a threading 2684. For example, an adjusting nut 2685 is provided as an adjustment means for the individualization fingers (see
The fifth individualization roller 235a is situated adjacent in the y-direction to the individualization finger 2656 with the associated elastic finger 26576, such that the individualization roller 235a overlaps with the individualization assembly (2656, 26576) without a gap. The inclination angle α of the approach plate 265 lies in a range from 28°-35° and is preferably α=32° relative to a straight dash-dot line that proceeds parallel to the transport direction x, at a distance m from the supply deck 12 of the placement station or from the supply deck 22 of the supply station. An imaginary vertical line (not drawn) between the aforementioned edge of the approach plate 265 and the aforementioned straight dash-dot line m has a height of h1min. The first and second subset of the stack ST of flat goods together have a height h=h1min+h2max and are let through below the stack stop wall 281 that is stationary in the operating mode, wherein the stack stop wall 281 forms a first sluice stage of a pre-sluice. The third subset has a height h3.
Although the first subset of the stack ST of flat goods may theoretically have a height h1min, only a first flat good G1 of medium thickness exists in the schematic depiction according to
Shown in
A section detail of the individualization station from the left is depicted in
The individualization fingers 2655 to 2656 and the separate roller body 235a lie in a second sluice region 32. The center of the running surface of the separate fifth roller body 232a is arranged at a third distance c≤¾ of the width of the B4 format of mail pieces, preferably c=18.25 cm, from the vertical alignment wall 21. The second sluice region 32 ends at a fourth distance d≥⅘ of the width of the B4 format of mail pieces, preferably at a distance d=20.15 cm, from the vertical alignment wall 21. The second sluice region 32 preferably has a width of g=3.8 cm. An edge of the first sluice region 31 that is situated next to the vertical alignment wall 21 is preferably situated at a distance a+e/2=(4.5−8.3/2) cm=0.35 cm. An edge of the first sluice region 31 that is situated farther distant from the vertical alignment wall 21 is preferably situated at a distance a+e/2=(4.5−8.3/2) cm=8.65 cm. The latter distance a+e/2 preferably lies at a distance f=c−g/2−(a+e/2)=18.25−3.8/2−(4.5+8.3/2) cm=16.35−8.65 cm=7.7 cm from the inner edge of the second sluice region 32. Each separate roller body is likewise equipped with integrated freewheel mechanism. The first, second and third roller bodies 231a, 232a and 233a of the structured drum body of the first drum 23a have a diameter of approximately 4 cm and are preferably 1.0 to 1.2 cm wide and are spaced by an equal distance from one another. They respectively protrude through a corresponding opening 201, 202, 203 in the first part 221 of the supply deck. The first distance a is less than the second distance b. The second distance b is less than the third distance c, and the third distance c is less than the fourth distance d. a<b<c<d applies. The drum body 23a runs on the driven rotation axle shaft 230a. The openings 201, 202, 203, 204 for first, second, third, fourth roller bodies are provided in the first part 221 of the supply deck 22, and only one opening 205 for the fifth roller body 235a is provided In the second part 222 of the supply deck 22. The first, second, third and fifth roller bodies are situated opposite the individualization assembly in order to form a sluice through which a flat good to be individualized passes via traction. The separate fourth roller body 234a passes in the z-direction, at a second distance b, through a fourth opening 204 in the first part 221 of the supply deck. A rubber layer is likewise installed on the separate fourth roller body 234a. The separate fifth roller body 235a is arranged at a much greater third distance c from the vertical alignment wall 21 and is provided with a fifth rubber-jacketed roller, and passes through a fifth opening 205 in the second part 222. The separate roller bodies 234a and 235a, together with a respective freewheel mechanism, are installed on the driven rotation axle shaft of the first drum 23a.
Alternatively, an extended, structured drum body of the first drum 23a may be used again that has at least one additional roller body structure.
The three layers or jackets of the roller bodies 231a, 232a, 233a of the first drum 23a, and the individualization fingers 2651 through 2656, are formed of a plastic or rubber, or of another material having a very high coefficient of friction given use with flat goods, which are preferably mail pieces made of paper or paperboard. The outer layer of the other roller bodies 234a, 235a are likewise formed of plastic or rubber or a different material having a very high coefficient of friction.
In addition to the opening 26910, the first right-angled bend 2691 has an additional opening 26911 for the arresting pin 273 for guidance of the carrier plate 269 for linkage guidance, wherein the carrier plate 269 for linkage guidance is arranged so as to be transversally displaceable in the y-direction on the stationary axle 2680 and on the arresting pin 273.
A portion of the stationary axle 2680 is situated at a closer distance, near the carrier angle plate 2751, and has a larger diameter D1. Two contact pressure fingers 2681, 2682 are elastically and rotatably installed on this part of the stationary axle with a respective contact pressure finger spring 26811, 26821.
Another portion of the stationary axle 2680 is placed at a farther distance from the carrier angle plate 2751 and has a smaller diameter D2 than D1. The other portion of the stationary axle 2680 is designed bolt-shaped, with the smaller diameter D2, and has a bolt threading 2684 at its outstanding end. A compression spring 2683 is installed on this portion of the stationary axle 2680 with the smaller diameter D2.
The carrier plate 269 for linkage guidance is curved in a u-shape so that an inner wall of the first right-angled bend 2691 and an inner wall of the second right-angled bend 2692 are arranged facing and parallel to one another. A shoulder at the portion of the stationary axle 2680 having the smaller diameter D2 forms a first stop for the one end of the installed compression spring 2683, and the inner wall of the second right-angled bend 2692 forms a second stop for the other end of the installed compression spring 2683. An adjusting nut 2685 is installed on the threading 2684, which threading 2684 protrudes through opening 26920. Via the adjusting nut 2685, the carrier plate 269 for linkage guidance may be adjusted in the y-direction and counter to this, and the extension arm 2641 pivots as well corresponding to the adjustment because the ball bearings 2693, 2694 travel in the guide channel of the retention plate, which ball bearings 2693, 2694 are installed at the plate tab 2695 and at the transversally displaceable carrier plate 269 for linkage guidance (
Although modifications and changes may be suggested by those skilled in the art, it is the intention of the Applicant to embody within the patent warranted hereon all changes and modifications as reasonably and properly come within the scope of the Applicant's contribution to the art.
Number | Date | Country | Kind |
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202016106124.5 | Nov 2016 | DE | national |