EP0520188A1 - Mechanism for letter file - Google Patents

Abstract

The invention relates to a mechanism for a letter file, having a baseplate (10), two sorting pins (12) which project above the baseplate, a folding bar (18) which is mounted so as to be limitedly pivotable on the baseplate (10), an end shield (20) which projects above the baseplate (10) in the region between the sorting pins (12) and the folding bar (18), and an actuating lever (22) which is mounted pivotably on the end shield (20) and acts on a bend (26) in the folding bar (18) counter to the force of a spring (42). In order to achieve easier handling of the mechanism for letter files with the smallest possible pivoting path of the actuating lever (22), a glissette element (28) made of plastic is arranged in the region of the bend (26) in the folding bar (18) and has a sliding surface (36), which projects obliquely above the plane defined by the bend (26) and opens out at its upper end into a catch depression (40), for a lever arm (46) of the actuating lever (22) formed at its tip as a sliding and catch cam (44). In order to achieve a linear contact over the entire pivoting range of the actuating lever (22) between the sliding surface (36) and the sliding and catch cam (44), the sliding surface (36) of the glissette element (28) is coiled in a helical manner in the direction of displacement of the sliding and catch cam (44). <IMAGE>

Description

The invention relates to a folder mechanism with a base plate, preferably made of sheet metal, two, preferably metallic, line-up pins protruding perpendicularly from one another on the base plate, one pivotable to a limited distance from the line pins by means of a bearing web on the base plate between an open position and a closed position, two by the bearing web at a distance from the aligning pins to one another and having folding legs which can be coupled in pairs in the closed position, preferably consisting of a bent metal wire, a folding bracket in the area between the aligning pins and the folding bracket projecting over the base plate, preferably integrally connected to this bearing block and an am Bearing block about an actuating lever which is pivotably mounted transversely to the axis of the bearing web and acts on a cranking of the bearing web against the force of a spring.

The file mechanism is intended for letter folders, which consist of a file spine and a front and rear cover hinged to it, preferably made of stiff cardboard material. The folder mechanism is attached to the back cover of the letter folder in the vicinity of the folder back, preferably riveted or inserted into a holder provided for this purpose, so that the folding bracket can be pivoted into its open position by actuating the actuating lever in the direction of the folder back and opening an opening between the filing pins and the bracket. In this state, perforated documents can be inserted or removed on the side of the alignment pins after any layers of documents that may have been placed above them have been moved onto the folding hanger with the mechanics still closed. In the closed state, the folder mechanism reaches with its alignment pins and its folding bracket from the back cover through the folder to the front cover and, if necessary, engages with the bent ends of the folding legs in push-through slots of the front cover provided with locking lugs.

In the conventional folder mechanisms, the actuating lever made of a metal wire is designed as a toggle lever, which is articulated at one end by means of a rivet to a bearing plate bent out of the base plate and by means of a steel pin which is eccentrically arranged in the knee region of the lever and carries a plastic tube or a profiled roller abuts the bow offset at the top. Next is against the crank part from below a leaf spring mounted on the base plate under pretension, which ensures that the folding bracket automatically takes with it the parts of the document placed on it when the actuating lever is released into its initial position and is held in this position. To close the folding handle, the actuating lever is depressed and the steel pin, together with the cranking part, is pivoted downward against the force of the spring until the alignment pins and the associated stirrup legs are pressed against one another with their conically interlocking end faces and the steel pin is in its closed position beyond the dead center brought. In the closed position of the steel pin, the operating lever strikes the base plate with an extension arm. To operate the known folder mechanism, a relatively large swivel path of the actuating lever is required, which leads to the actuating lever in the open state it comes close to the hook-in opening on the side of the folding handle and blocks it against hooking and unhooking documents.

Proceeding from this, the object of the invention is to develop an easy-to-use folder mechanism, the actuating lever of which has a small swivel path.

To achieve this object, the combination of features specified in claim 1 is proposed according to the invention. Further advantageous refinements and developments of the invention result from the dependent claims.

The invention is based on the knowledge that the closing process (and vice versa the opening process) of the folder mechanism takes place in two phases, the movement phase in which the folding handle is pivoted against the alignment pins while reducing the insertion and removal opening, and the closing phase in which the closing force is built up between the alignment pins and the folding handle. In order to achieve a short swivel path of the actuating lever, it is therefore necessary to ensure that an optimal transmission ratio between lever and folding arm movement is set in the movement phase in adaptation to the spring forces to be overcome and that the necessary closing force - in contrast to the conventional folder mechanisms - is included the shortest possible leverage is established. In order to achieve this, it is proposed according to the invention that a plastic sliding curve element is arranged in the region of the crank of the bearing web on the folding bracket, which has an oblique protrusion beyond the plane spanned by the crank, opening at its upper end into a rest area Has sliding surface for a lever arm of the actuating lever designed at its tip as a sliding and latching part. The locking point of the sliding curve element is expediently designed as a locking recess, while the sliding and locking part of the actuating lever is designed as a sliding and locking cam which can be locked into the locking recess. In a kinematic reversal of this, the latching point of the sliding curve element can also be designed as a latching cam, while the sliding and latching part of the actuating lever can have a latching recess which can be latched onto the latching cams. Finally, a latching connection can also be produced in that the latching point of the sliding curve element and the sliding and latching part of the actuating lever have latching surfaces which abut against one another under pretension.

With the measures according to the invention it is achieved that only a relatively short rest distance has to be overcome in order to produce the required closing force and that in the movement phase the transmission ratio between lever travel and bow travel can be freely selected within wide limits via the slope of the sliding surface and is therefore optimally adaptable. Overall, the pivoting path of the lever required for actuating the file mechanism can be optimally adapted to the given spatial conditions. Plastic has proven to be particularly advantageous as the material pairing between the sliding curve element and the lever sliding on it. In order to keep the pressure and abrasion forces that occur as small as possible, it is proposed according to a preferred embodiment of the invention that the sliding and locking cams of the actuating lever are wedge-shaped in cross-section and one that lies linearly against the sliding surface over the entire pivoting range of the actuating lever and into the recess engaging wedge tip. If one takes into account that the sliding curve element rigidly connected to the crank part of the folding bracket is pivoted relative to the actuating lever during the closing and opening process, it has proven to be advantageous if the sliding surface is helically wound in the direction of displacement of the sliding and latching part, so that in each Pivotal position of the lever a linear contact between the wedge tip and sliding surface is possible. In terms of design, this can be achieved in that the sliding surface is delimited by two side flanks having a different angle of attack with respect to the plane spanned by the offset, the side flank facing the bearing block being steeper than the other side flank. The difference between the angles of attack is expediently 6-14 °, preferably 9-11 °, the angle of attack of the side flank facing the bearing block with an optimal transmission ratio in the movement phase being 50-60 ° and that of the other side flank 60-70 °.

According to a further advantageous embodiment of the invention, the sliding surface is separated at the top by a latching edge from the latching recess and at the bottom by an edge of the foot from an adjacent foot part, the latching edge and the foot edge enclosing an acute angle which is open towards the bearing block and which in the Frontal projection seen 10 to 24 °, preferably 15 to 19 °. These measures also contribute to the fact that a linear and non-punctiform contact occurs between the sliding and locking part of the actuating lever on the one hand and the sliding surface on the other hand over the entire swivel range. The locking edge at the upper end of the sliding surface is substantially perpendicular with respect to the base plate The pivot axis of the actuating lever is arranged while the locking recess is on the side of the locking edge facing away from the sliding surface. With this measure, an additional securing of the lever in the closed position is achieved by exceeding the dead center of the lever. A further improvement in this regard is achieved in that the latching recess is limited by a rear flank on the sliding curve piece which is higher than the latching edge.

Since the pivoting of the sliding curve piece relative to the lever in the course of the movement additionally results in a lateral relative displacement between the sliding and locking cams on the one hand and the sliding surface on the other hand, it is expedient to make the wedge tip forming the sliding and locking cams wider than the sliding surface of the sliding curve element.

With the measure according to the invention, it is possible to design the actuating lever in adaptation to the sliding curve element in such a way that it moves upwards from the base plate at an angle of less than 25 ° in the open position and at an angle of less than 10 in the closed position ° towards the base plate facing downward actuating arm, the actuating arm and the lever arm of the two-armed actuating lever carrying the sliding and locking cams expediently enclose an angle of 75-95 ° with one another.

The actuating lever, which is made of plastic, can either be mounted on one side on a bearing plate bent out of the base plate and forming the bearing block, or on two sides on a box-shaped bearing block that overlaps the crank.

In principle, it is possible to spray the plastic sliding curve element onto the cranked part of the folding bracket. According to a preferred embodiment of the invention, the sliding curve element has an open-edged latching opening for snapping onto the cranked part of the folding bracket, at least one pinch wedge produced by cold deformation and projecting on one side can be arranged on the cranking part, onto which the sliding curve element is positively latched with a correspondingly designed recess can be. The sliding curve element is oriented on the crank part with its sliding surface on one side in the direction of the actuating lever. To make assembly easier, however, it is advantageous if the sliding curve element has two sliding surfaces and detents arranged symmetrically to one another against rotation by 180 °, only one of which is effective in the assembled state.

To avoid the risk of injury and to improve the appearance, a cover part that overlaps the sliding and locking cams and the bearing block can be formed on the actuating lever.

In kinematic reversal, it is fundamentally possible to arrange, preferably to form, the sliding curve element having the sliding surface and the locking recess on the actuating lever and the sliding and locking cams on the offset part of the folding bracket. However, this alternative is associated with constructional and material-technical difficulties, which require considerable additional effort.

Fig. 1a und b

eine Stirnseitenansicht einer Ordnermechanik im offenen und geschlossenen Zustand;

Fig. 2a und b

eine Vorderansicht der Ordnermechanik im offenen und geschlossenen Zustand;

Fig. 3

eine Draufsicht auf die Ordnermechanik ohne Betätigungshebel;

Fig. 4

einen senkrechten Schnitt durch die Ordnermechanik im Bereich des Betätigungshebels in vergrößerter Darstellung;

Fig. 5a bis c

eine vergrößerte Darstellung eines Gleitkurvenelements in einer Seitenansicht, einer Stirnseitenansicht und einer Draufsicht;

Fig. 6a bis c

ein abgewandeltes Ausführungsbeispiel eines Gleitkurvenelements in einer Seitenansicht, einer Stirnseitenansicht und einer Schnittdarstellung.

In the following, the invention will be explained in more detail with reference to some exemplary embodiments shown schematically in the drawing. Show it:

1a and b

an end view of a folder mechanism in the open and closed state;

2a and b

a front view of the folder mechanism in the open and closed state;

Fig. 3

a plan view of the folder mechanism without an operating lever;

Fig. 4

a vertical section through the folder mechanism in the region of the actuating lever in an enlarged view;

5a to c

an enlarged view of a sliding curve element in a side view, an end view and a plan view;

6a to c

a modified embodiment of a sliding curve element in a side view, an end view and a sectional view.

The folder mechanism shown in the drawing is intended for installation in letter folders. It essentially consists of a base plate 10 made of sheet metal, which can be fastened to the back cover of a letter folder, two metallic line-up pins 12 projecting vertically at a distance from one another on the base plate 10, a folding bracket 18 pivotably mounted by means of a bearing web 14 on two bearing brackets 16 which are bent out from the base plate at a distance from one another , a bearing plate 20 bent out of the material of the base plate in the area between the alignment pins 12 and the folding bracket 18 and an actuating lever 22 pivotably mounted on the bearing plate 20. The folding bracket consisting of a bent metal wire also has two the ends of the bearing web 14 bent upwards and with their free ends to the alignment pins 14 curved down leg 24, which can be coupled in the closed position with one of the alignment pins 12 at the end (Fig. 1a) and in the open position an opening for hanging Release documents on the alignment pins and / or the folding hanger (Fig. 1b). The folding bracket 18 also has in the central region of the bearing web 14 a cranking part 26 on which a sliding curve element 28 made of plastic is snapped in a positive and non-positive manner. For this purpose, the offset part 26 is provided with a crimping wedge 30 which is molded on by cold deformation and which engages in a form-fitting manner in a correspondingly shaped recess 32 which is open at the edge within the latching recess 34 of the sliding curve element 28 and which comprises the offset part (FIGS. 4 and 5).

On its end face facing the actuating lever 22, the sliding curve element has a sliding surface 36 which points obliquely upwards from the cranking part 26 and opens upwards into a transverse locking recess 40 via a locking edge 38. The sliding curve element 28 is pressed upwards from below via a spring 42 acting against the offset 26, so that it rests against the wedge-shaped sliding and latching cams 44 of the actuating lever 22 with its sliding surface 26 or its recess 40 in every pivoted position of the actuating lever 22 . The sliding and latching cam 44 forms the tip of a lever arm 46 which in the area of the pivot bearing 48 projects substantially downward approximately perpendicular to the actuating arm 50. As can be seen in particular from FIG. 4, the wedge tip 52 of the sliding and latching cam 44 is somewhat wider than the sliding surface of the sliding piece. By an appropriate helically coiled shape of the sliding surface 36 is achieved that the sliding and locking cam 44 with its wedge tip 52 lies linearly against the sliding surface 36 in each pivoting position of the actuating lever 22 and engages in the locking recess 40 over the entire width. This shape of the sliding surface can best be seen in FIGS. 5a and 5c and FIGS. 6a and b. 5a to c shows an asymmetrical sliding curve element with an upwardly tapering sliding surface 36, the sliding curve element shown in FIGS. 6a to c is designed to be rotationally symmetrical by 180 ° to facilitate assembly, with only one of the sliding surfaces 36 and the locking recesses 40 in each case assembled state. As can be seen in particular from FIGS. 5a and 6a, the side flank 54 of the sliding surface 36 facing the bearing plate 20 in the assembled state is steeper than the other side flank 56, so that the locking edge 38, which is approximately horizontal in the closed position, with the sliding surface 36 downward delimiting foot edge 58 in the front projection shown in FIGS. 5b and 6b includes an angle that is open toward the end shield. The rear boundary wall 60 of the latching recess 40 is somewhat higher than the latching edge 38 and thus ensures that the slide and latching cam 44 cannot emerge from the latching recess 40 to the rear when the actuating lever is further depressed.

The actuating lever, which is designed as a plastic injection-molded part, is inserted with a molded-on rivet pin 62 through a bearing bush 64 formed in the deep-drawing process in the bearing plate 20 and is provided on its free end face projecting over the bearing bush by hot deformation with a rivet head 66 serving as an axial bearing. The plastic operating lever is otherwise accessible to any shape. In particular, in the exemplary embodiment shown, a cover 68 which overlaps the bearing point and the upper edge of the bearing plate 20 is formed on the lever, which avoids a risk of injury to the ridges which may be present on the bearing plate.

In summary, the following can be stated:
The invention relates to a file mechanism with a base plate 10, two row pins 12 projecting from the base plate, a folding bracket 18 mounted on the base plate 10 so that it can be pivoted to a limited extent, a bearing plate 20 projecting beyond the base plate 10 in the area between the row pins 10 and the folder 18 an actuating lever 22, which is pivotably mounted on the end shield 20 and acts on a crank 26 of the folding bracket 18 against the force of a spring 42. In order to achieve easier handling of the folder mechanism with the smallest possible pivoting travel of the operating lever 22, a crank 26 of the folding bracket 18 is provided in the region of the crank Sliding curve element 28 made of plastic, which has a sliding surface 36 protruding obliquely beyond the plane spanned by the crank 26 and at its upper end opening into a locking recess 40 for a lever arm 46 of the actuating lever 22 designed as a sliding and locking cam 44 at its tip having. In order to achieve a linear contact between the sliding surface 36 and sliding and locking cams 44 over the entire pivoting range of the actuating lever 22, the sliding surface 36 of the sliding curve element 28 is helically wound in the direction of displacement of the sliding and locking cam 44.

Claims (28)

Folder mechanism with a base plate (10), preferably made of sheet metal, two, preferably metallic, line-up pins (12) projecting vertically at a distance from one another on the base plate, one at a distance from the line-up pins (12) by means of a bearing web (14) on the base plate (10) between an open position and a closed position, pivotally mounted, two folding brackets (18), preferably made of a bent metal wire, which are held by the bearing web (14) at a distance from the alignment pins and which can be coupled with these in pairs in the closed position, one in the area between the Alignment pins (12) and the folding bracket (18) projecting beyond the base plate (10), preferably integrally connected to the bearing block (20), and a bearing block (20) on the bearing block (20) which is pivotally mounted to a limited extent transversely to the axis of the bearing web (14) a crank (26) of the bearing web (14) against the force of an Fe the (42) acting actuating lever (22), characterized by a sliding curve element (28) made of plastic which is arranged in the region of the crank (26) of the bearing web (14) on the folding bracket (18) and which is inclined across the crank (26) Level protruding, at its upper end into a locking point (40) sliding surface (36) for a lever arm (46) of the actuating lever (22) formed at its tip as a sliding and locking part (44). File mechanism according to claim 1, characterized in that the latching point of the sliding curve element (28) is designed as a latching recess (40) and the sliding and latching part of the actuating lever (22) is designed as a sliding and latching cam (44) which can be latched into the latching recess (40). Folder mechanism according to claim 1, characterized in that the latching point of the sliding curve element (28) is designed as a latching cam and that the sliding and latching part of the actuating lever has a latching recess which can be latched onto the latching cams. Folder mechanism according to claim 1, characterized in that the latching point of the sliding curve element and the sliding and latching part of the actuating lever have latching surfaces which abut against one another under pretension. Folder mechanism according to claim 2, characterized in that the sliding and latching cam (44) of the actuating lever (22) is wedge-shaped in cross-section and a linear over the entire swivel range of the actuating lever (22) against the sliding surface (36) and into the latching recess (40) has a snap-in wedge tip (52). File mechanism according to one of claims 1 to 5, characterized in that the sliding surface (36) is helically wound in the direction of displacement of the sliding and locking part (44). File mechanism according to claim 5 or 6, characterized in that the wedge tip (52) delimiting the sliding and locking cams (44) is wider than the sliding surface (36) of the sliding curve element (28). File mechanism according to one of claims 1 to 7, characterized in that the sliding surface (36) with the plane spanned by the base plate (10) includes a sliding angle for the sliding and latching cams (44) of 55-70 ° in each pivoting position of the actuating lever . File mechanism according to claim 8, characterized in that the sliding surface has an essentially constant sliding angle over the entire pivoting range of the actuating lever (22). Folder mechanism according to claim 8, characterized in that the sliding surface (36) has a sliding angle which decreases continuously from the offset (26) to the locking recess (40). Folder mechanism according to Claim 8, characterized in that the sliding surface (36) has a sliding angle which is initially constant or increasing and then decreasing from the offset (26) to the locking recess (40). File mechanism according to one of claims 1 to 11, characterized in that the sliding surface (36) is delimited by two side flanks (54, 56) which have a different angle of attack with respect to the plane spanned by the crank (26), the line-up pins (12) facing Side flank (54) is steeper than the other side flank (56). File mechanism according to claim 12, characterized in that the difference between the angles of attack is 6 - 14 °, preferably 9 - 11 °. Folder mechanism according to Claim 12 or 13, characterized in that the angle of attack of the side flank (54) facing the aligning pins (12) is 60-70 ° and that of the other side flank is 50-60 °. Folder mechanism according to one of claims 1 to 14, characterized in that the sliding surface (36) has a latching edge (38) which is arranged substantially perpendicularly below the pivot axis (64) of the actuating lever (22) with respect to the base plate (10), and in that the latching recess (40) is arranged on the side of the latching edge (38) facing away from the sliding surface (36). File mechanism according to claim 15, characterized in that the latching recess (40) is delimited by a rear wall (60) which is higher than the latching edge (38). Folder mechanism according to one of claims 12 to 16, characterized in that the sliding surface (36) is separated upwards by a locking edge (38) from the locking recess (40) and downwards by a foot edge (58) from an adjacent foot part, and that the locking edge (38) and the foot edge (58) enclose an acute angle open towards the alignment pins (12). Folder mechanism according to claim 17, characterized in that the angle between the latching edge (38) and the base edge (58) seen in the front projection (FIG. 5b) is 10-24 °, preferably 15-19 °. File mechanism according to one of claims 1 to 18, characterized in that the sliding curve element (28) has two sliding surfaces (36) and locking points (40) arranged symmetrically to one another against rotation by 180 °. File mechanism according to one of claims 1 to 19, characterized in that the actuating lever (22) moves upwards in the open position at an angle of less than 25 ° from the base plate (10) and in the closed position at an angle of less than 10 ° to the base plate (10) pointing downward actuating arm (50). File mechanism according to claim 20, characterized in that the actuating arm (50) and the lever arm (46) of the two-armed actuating lever (22) carrying the sliding and latching cam (44) enclose an angle of 75-95 ° with one another. File mechanism according to one of claims 1 to 21, characterized in that the plastic operating lever (22) is supported on one side on a bearing plate (20) which is bent out of the base plate (10) and forms the bearing block. File mechanism according to one of claims 1 to 21, characterized in that the actuating lever (22) made of plastic is attached to one side on two the crank (26) overlapping box-shaped bearing block is mounted. File mechanism according to one of claims 1 to 23, characterized in that the sliding curve element (28) has an open-edged latching recess (34) for snapping onto the crank part (26) of the folding bracket (18). File mechanism according to one of claims 1 to 23, characterized in that the sliding curve element (28) is sprayed onto the cranked part (26) of the folding bracket (18). Folder mechanism according to one of claims 1 to 25, characterized in that at least one pinch wedge 30, which protrudes on one side and is produced by cold deformation, is arranged on the offset part (26) of the folding bracket (18), and in that the sliding curve element (28) positively engages the pinch wedge (30) has receiving recess (32). File mechanism according to one of Claims 1 to 26, characterized in that a cover part (68) which overlaps the sliding and locking cams (44) and the bearing block (20) is integrally formed on the actuating lever (22). Folder mechanism according to one of claims 1 to 27, characterized in that the kinematic reversal of the sliding curve element having the sliding surface and the locking recess on the actuating lever (22) and the sliding and locking cams on the crank part (26) of the folding bracket (18) is arranged, preferably integrally formed .

Images