EP0322355A1 - Venetian blind - Google Patents

Abstract

The Venetian blind (7) has a slat angle adjustment device which has a pulley (53). The step pulley (53), which adjusts the angle of inclination on lowering as well as on raising of the slats (5), can be adjusted to the desired value at any time from outside. <IMAGE>

Description

The present invention relates to a roman blinds according to the preamble of claim 1.

In the case of slat stores of this type, where the position of the slats can be adjusted by means of foldable vertical connections (e.g. link or link chains) accommodated on the side in guide rails, the angle of inclination during lowering or lifting is preset at the factory. A subsequent change and adjustment of the inclination angle of the store on the building is not possible with the well-known Roman blind.

A Roman blind is also known (ARS system from Hüppe GmbH, D-2900 Oldenburg), in which, in addition to a standard inclination angle, a flatter and a steeper angle can be set at the factory when lowering the store. In contrast to the above, this known store has no articulated chains with which the slats are adjusted, but rather an adjustment mechanism made of textile connecting elements which is attached in the visible area of the slats. By means of a reversing gear unit with changeover mechanism in the head channel, the angle that the Take slats when lowering, set differently from the standard value. It is not possible to transfer this known technology to stores with articulated chain actuators concealed in the side guides.

The invention seeks to remedy this.
The invention, as characterized in the claims, solves the task of creating a store in which, with simple means, the angle of inclination of the slats in the lowering phase to the local conditions (south facade, west or east facade, etc.) or depending The type of use of the room (e.g. work room with screen devices, etc.) can be adapted and, if necessary, changed later.
The main advantage of the invention is that the angle of inclination can be adjusted without dismantling the elevator device and can also be subsequently adapted to the conditions of the location of the store and the type of use of the space behind it.
Another advantage is that, thanks to the spring built into the drive, the drive shaft can be rotated further after the store has been completely lowered without the drive wheel turning too. This makes it possible to compensate for inaccuracies in parking, in particular in the case of electric drives, and to prevent a vertical movement during pivoting of the slats in the lowest position, which would cause a gap between the lowest slat and the ledge.

• Figur 1 einen Längsschnitt der Seitenführung mit der Stu­fenscheibe,
• Figur 2 einen Querschnitt längs Linien II-II in Figur 1, wobei im hinteren Bereich der Schnitt längs Linie II′-II′ verläuft,
• Figur 3 einen Schnitt längs Linie III-III in Figur 1,
• Figur 4 eine schematische Darstellung der Vorrichtung wäh­ rend des Hochziehens des Stores,
• Figuren 5-7 je eine schematische Darstellung mit verschiedenem Neigungswinkel während des Absenkens des Stores und
• Figur 8 eine Darstellung des geschlossenen Stores.

The invention will be explained in more detail with the aid of drawings illustrating the embodiment. Show it:

• FIG. 1 shows a longitudinal section of the side guide with the stepped washer,
• FIG. 2 shows a cross section along lines II-II in FIG. 1, the section along the line II′-II ′ running in the rear region,
• FIG. 3 shows a section along line III-III in FIG. 1,
• Figure 4 is a schematic representation of the device pulling up the store,
• FIGS. 5-7 each show a schematic illustration with a different angle of inclination during the lowering of the store and
• Figure 8 shows the closed store.

For better understanding of the invention, FIG. 1 shows the most important elevator and adjustment mechanisms for lifting, lowering and pivoting the slats 5 of the store 7, which are arranged in the side guide 1 and in the above them, accommodated in a housing 3.
In the housing 3 of the elevator mechanism, a drive and deflection wheel 11 is placed on a shaft 9, which connects the two side guides 1. The drive wheel 11 can be fixedly connected to the shaft 9, or a coupling can be inserted between the shaft 9 and the drive wheel, which allows the shaft 9 to rotate in at least one direction with respect to the drive wheel 11 by, for example, an angle of rotation of 100 degrees, without being taken along. A helically or helically wound spring 13 can be provided as the coupling member, one end of which is connected to the shaft 9 and the other end of which is connected to the drive wheel 11 (FIG. 3). About the drive wheel 11 runs a tension member 15 in the form of a perforated sheet metal strip, a plastic band or rope or a link chain, at one end of a locking member 17 and at the other end a control cam 19 is attached. The holes or recesses 21 in the tension member 15 engage on the periphery of the drive wheel 11 with drivers 23 attached there. In the housing of the side guide 1 there are grooves 25 which can accommodate the tension member 15 in the extended position and with little play. On the side of the locking member 17, the groove 25 is preferably on a side surface; on the side of the control cam 19, the groove 25 is preferably substantially at an angle of approximately 45 degrees in the corner between the rear wall and the side wall of the side guide 1. In order that the traction element 15 cannot be lifted off the drive wheel 11, there is a short distance to the periphery of the drive wheel 11, a guide plate 27. Instead of a guide plate 27, the housing 3 can of course, especially if it is made of plastic it is necessary to take the lead yourself.

In the side guide 1 there is also a guide track 29 in which a slide shoe or a slide roller 31, which is attached to a carriage 33 and guides it on a vertically running track. The carriage 33 is arranged parallel to the rear wall of the side guide and consists of a profiled sheet or plastic and is suspended from a pair of link chains 37 and latched onto the locking link 17 in the operating state. The link chain pair 37 of known design hangs on a rocker 39 pivotably arranged on the shaft 9. The rocker 39 consists of two arms 41, to which the two chains of the link chain pair 37 are fastened by means of ropes 35. In addition to the rocker 39, a brake cylinder 43 with a spring 45 wound helically thereon is arranged on the shaft 9 in a rotationally fixed manner. The two ends 47 of the spring 45 project radially outward from the brake cylinder surface (FIG. 3). A driving segment 49, which is part of the rocker 41, projects axially between the two ends 47 into a recess 51 in a step plate 53 placed next to the brake cylinder 43 on the brake cylinder 43. The step plate 53 is rotatably mounted on the shaft 9 and has a in the lower area four levels A, B, C and D and in the upper area another opposite level E. The jumps in the individual stages preferably run radially.

On the right side wall of the housing 3, a vertically lying polygonal shaft 55 is rotatably supported on the inside, at the lower end of which a first radially projecting lever 57 is rotatably mounted and on the upper part of which a likewise radially projecting retaining finger 59 is vertically slidably mounted on the shaft 55.
In its highest possible position (FIG. 1), the holding finger 59 comes into contact with the step A of the step plate 53. The holding finger 59 can be lowered with a sliding device 61 in order to engage either step B or step C. The end of the lever 57 is located next to the groove 25 in which the tension member 15 is guided with the control cam 19.

When the control cam 19 runs into the pivoting range of the lever 57, the lever 57 is pivoted by the control cam 19 together with the retaining finger 59 seated on the polygonal shaft 55. During this pivoting, the end of the holding finger 59 comes to lie to the side of the step plate 53 and is no longer in engagement with one of the steps A-C of the step plate 53.

In the travel path of step D on the step plate 53 there is an abutment 65 arranged eccentrically on a rotary knob 63. The rotary knob 63 is mounted in a bore 67 in the front of the side guide. Instead of an eccentric stop 65, a plurality of bores 66 can also be made at a lateral distance, into which a stop pin can be inserted and the travel path of the stepped disk 53 can be limited.

The step E on the step plate 53 comes into abutment with a stop pin 69, which is also arranged on the front of the housing of the side guide 1 and protrudes into the housing 3. The stop pin 69 can be designed in a manner analogous to that of the rotary knob 63 or made up of several arranged on a circular path Bores 71 exist, into each of which a locking pin can be inserted, which restricts the rotational movement of the stepped disk 53 or is cast on the housing 3.

The mode of operation of the roman blind according to the invention is explained in more detail below.

In the position according to FIG. 4, as is the case when the slats 5 are pulled up, the shaft 9 is rotated clockwise by a manual or electric drive acting on the end of the shaft 9. The edge E of the stepped washer 53 comes into contact with the stop pin 69, which is inserted into the corresponding bore 71 depending on the desired elevator inclination angle of the slats 5. The stepped disk 53 now remains in the position given by the stop 69 during the entire mounting process. With the step plate 53, the rocker 39, which has been rotated by the segment 40, is in a position in which the arms 41 come to lie substantially perpendicular. The link chains 37 suspended from the arms 41 hold the slats 5 in the set inclined position of, for example, 0, 15, 30 degrees or another angle of inclination until they are placed on the stack of slats 5 which rises from the bottom up.

When the slats 5 are lowered, the shaft 9 is rotated counterclockwise by turning the hand crank or by the drive motor. The spring 45, which is firmly seated on the rotationally fixed brake cylinder 43, engages the segment 40 and rotates with it both the rocker 39 and the stepped disk 53 until one of the edges C, B or A comes into contact with the holding finger 59.

The position of the stepped disk 53 in FIG. 5 causes an angle of inclination of the slats 5 of approximately 30 degrees. If the finger 59 were set by the sliding device 61 in such a way that it would come into engagement with the edge B, then an angle of inclination of approximately 50 degrees would result (FIG. 6) and an angle of inclination of approximately 70 degrees when engaged with the edge C. (Figure 7).

As soon as the lowest slat 5 approaches the lowest possible position, the lever 57 is pivoted by the control cam 19. This pivoting movement, which is transmitted from the polygonal shaft 55 to the retaining finger 59, pushes the latter out of the contact area with the stepped washer 53, whereby this can perform a further counterclockwise movement until its edge D comes into contact with the stop 65. In this position, the arms 41 of the rocker 39 are again approximately in a vertical position and the slats 5 connected to the pair of link chains 37 by means of the transverse levers 38 are in the vertical closed position.
In order to be able to compensate for inaccuracies in the entire device, which prevent the individual slats arranged one above the other from lying against one another in the closed position, the stop 65 can be finely adjusted by turning the rotary knob 69 until the edges of the slats 5 lie one on top of the other.

Thanks to the spring 13 arranged between the drive wheel 11 and the shaft 9, the shaft 9 can be rotated further, for example by an amount of up to 100 degrees, after the lowering movement of the lamellae 5, without causing damage to the device. This makes it possible to work with simple limit switches for motor drives, in which the end position does not have to be set very precisely. Furthermore, the additional rotation of the shaft 9 after the slats 5 have been completely lowered means that when opening, i.e. when rotating the shaft 9 to raise the slats 5, first pivot the latter into the position described in FIG. 4 before lifting the lowest slat 5 begins.

Claims (9)

1. Roman blinds (7) with a constant angle of inclination of the slats (5) during the lowering of the store and a pulling element (15) arranged in the side guides (1) for lifting and lowering the store (7), a horizontal drive shaft (9) and a link chain pair (39) arranged in a lateral guide (1) for pivoting the lamellae (5), characterized in that a disc (53) placed on the shaft (9) has a plurality of rockers (rotational angle of the link chains (37)) 39) has limiting stops A, B, C which can be brought into abutment with an adjustable holding finger (59). 2. Roman blind according to claim 1, characterized in that the holding finger (59) with completely lowered slats (5) by a control cam (19) on the tension member (15) can be swung out of the area of the disc (53). 3. Roman blinds according to claim 1 or claim 2, characterized in that the stops (A to C) from peripherally attached to the disc (53), substantially radially extending steps between segments with different radii. 4. Roman blinds according to one of claims 2 or 3, characterized in that the holding finger (59) is fastened to a polygonal shaft (55) on which a swivel arm (57) lying at a short distance from the pulling element (15) is attached. 5. Roman blind according to one of claims 2 to 4, characterized in that the retaining finger (59) by a sliding and locking device (61) axially on the polygonal shaft (55) and from this in predetermined, in the pivoting range of the stops A to C. lying positions can be locked. 6. Roman blind according to one of claims 1 to 5, characterized in that on the disc (53) a further step (E) is attached, which comes into contact with an adjustable stop (69) which the pivoting angle of the rocker (39) when pulling up the slats (5). 7. Roman blind according to one of claims 2 to 6, characterized in that on the disc (53) a step (D) is attached, which comes into contact with a stop (65) after the pivoting of the holding finger (59), the Defines the angle of inclination of the closed slats (5). 8. Roman blind according to claim 7, characterized in that the stop (65) for compensating for inaccuracies in the elevator mechanism and / or the slats (5) is arranged adjustable. 9. roman blind according to one of claims 1 to 8, characterized in that the disc (53) by a on the rocker (39) attached segment (40) on the brake cylinder (43) is pivotable.

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