DE29505382U1 - Screed for a paver - Google Patents

Description

Description ;

The invention relates to a screed for a road surface finisher according to the preamble of claims 1 and 10.

The working width of a road surface finisher is determined by the width of the screed. The width of the screed and thus the working width of the road surface finisher can usually be influenced by so-called sliding screeds, which are mounted on opposite ends of a main screed. The sliding screeds are mounted on the main screed in such a way that they can be extended laterally relative to the main screed on the one hand to adjust or adapt the working width of the road surface finisher and on the other hand can be moved up and down to adjust the height. Separate adjustment mechanisms are required for this. The invention relates to

an adjustment mechanism that ensures the height adjustment of the sliding planks in relation to the main plank.

The adjustment mechanism mentioned enables the height adjustment of the base plates of the sliding screeds relative to a base plate of the main screed. This is done for two purposes: Firstly, for example, in a new road surface finisher, before the first use of the screed, the base plates of each sliding screed are adjusted so that they have a certain relative position relative to the base plate of the main screed. This is usually only done once when the road surface finisher is put into operation. In addition, after this adjustment of the respective base plates of the sliding screeds and the main screed, the heights of the two are adjusted relative to each other so that the

is relative position is maintained and the floor panels only change their vertical distance from each other.

In known paving screeds, both the pre-adjustment of the base plates when the road surface finisher is put into operation, as well as the subsequent up and down movement of the base plates of the sliding screeds relative to the base plate of the main screed, are carried out using four adjustment elements arranged in each corner area of the corresponding base plate. The four adjustment elements are designed as screws or screw spindles and each can be adjusted or operated individually. This has proven to be disadvantageous, since after the pre-adjustment of the base plates of the sliding screeds and main screed, it must be ensured that each screw or screw spindle is adjusted by the same amount so that the set relative position of the base plates is maintained. The adjustment mechanism of known working screeds therefore requires a lot of adjustment and adjustment work.

Based on this, the present invention is based on the problem of creating a screed that enables a simplified height adjustment of the base plates of the sliding screeds relative to the base plate of the main screed.

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This problem is solved by a screed with the features of claim 1. Because at least two of the adjustment elements can be operated together, the height adjustment of the base plates requires considerably less work than with the prior art. With just one adjustment process, two adjustment elements can be adjusted synchronously at the same time.

Preferably, all adjustment elements are designed to be operated together. In this case, all adjustment elements can be adjusted simultaneously and synchronously with just one adjustment process. In this case, only one actuating element is required to adjust the height of the base element of a sliding screed relative to the base element of the main screed. When this actuating element is actuated, all adjustment elements of a sliding screed are adjusted simultaneously and by the same amount. With one adjustment process, the base element of a sliding screed can therefore be moved up and down relative to the base element of the main screed in such a way that the previously set relative position between the base plates is maintained.

According to a further advantageous embodiment of the invention, the screed has the features of claim 10. With the aid of the adjusting elements that can be actuated according to the invention, the side plate assigned to the outer side element of each sliding screed or the main screed can also be moved up and down with little effort.

Preferred developments of the invention emerge from the subclaims and the description. An embodiment of the invention is explained in more detail below with reference to the drawing. The drawing shows:

Fig. 1 an extended (left) half of a screed in a rear view (in relation to a production

direction) ,

Fig. 2 the extended half of the screed according to Fig. 1 in plan view, and

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Fig. 3 a cross-section through the extended half of the screed according to Fig. 1 and 2 after the section
IH-111 in Fig. 1.

The drawing shows the left half of a screed 11 for a road surface finisher (not shown otherwise) viewed from behind in the production direction 10. The screed 11 is attached behind the road surface finisher in the production direction 10.

The screed 11 is made up of a main screed 12 split in the middle, of which only a left half - a main screed half 13 - is shown in the drawing. The (left)

A sliding screed 14 is assigned to the main screed half 13. A main screed half (not shown) also has a sliding screed. The sliding screed 14 is mounted on the main screed half 13 via an intermediate slide 15. In contrast to this, it is conceivable that the paving screed 11 does not have an intermediate slide. In this case, the sliding screeds are mounted directly on the ends of the main screed. The sliding screed 14 is mounted on the main screed half 13 in such a way that the sliding screed 14 can be moved in and out laterally relative to the main screed half 13 on the one hand to adjust the working width of the road surface finisher and on the other hand can be moved up and down to adjust the height.

The main screed half 13 and the sliding screed 14 have approximately the same width. The sliding screed 14 can be moved relative to the main screed 13 transversely to the production direction 10, namely it can be extended and retracted. In the extended position, the sliding screed 14 doubles the width of the main screed half 13 and thus the working width of the road surface finisher.

The main screed half 13 has an outer side element at an outer end 16, namely an outer end plate 18. An opposite end 20 of the main screed pointing towards a longitudinal center axis 19 of the road surface finisher

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Half 13 also has a side element, namely an inner end plate 22. The end plates 18, 22 are rigidly connected to one another via a base element, namely a base plate 24.

The sliding screed 14 has two side elements, namely an outer plate 27 and an inner plate 28. The outer plate 27 and the inner plate 28 of the sliding screed 14 are also rigidly connected to one another, namely via a base element, which is designed as a base plate 30. The outer plate 27 and the inner plate 28 of the sliding screed 14 are divided, namely into lower parts 31, 32 and upper parts 33, 34. The lower parts 31, 32 of the outer plate 27 and inner plate 28 are rigidly connected to one another by the base plate 30.

The lower parts 31, 32, together with the base plate 30, are height-adjustable relative to the upper parts 33, 34 of the outer plate 27 and inner plate 28, namely designed to be movable up and down. This allows the distance between the base plate 30 of the sliding plank 14 and the base plate 24 of the main plank half 13 to be adjusted. To carry out this height adjustment, both the outer plate 27 and the inner plate 28 of the sliding plank 14 have an adjustment mechanism 35, which is described in detail below in connection with Fig. 3.

The adjustment mechanism 35 has two adjustment elements 36, 37, which can be operated together - i.e. synchronously at the same time - in pairs. Each adjustment element 36, 37 has a screw connector 38, 39 and a double-armed lever 40, 41. A lower end 42, 43 - a so-called eye piece - of the respective screw connector 38, 39 is connected in an articulated manner to the lower part 32 of the inner plate 28 of the sliding beam. Opposite ends 44, 45 of the respective screw connectors 38, 39 are connected in an articulated manner to a first arm 46, 47 of the double-armed lever 40, 41 assigned to them. Second arms 48, 49 of the double-armed levers 40, 41 are connected to one another by a further screw connector 50, so that the movement of one adjusting member 36 is transmitted to the other adjusting member 37.

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In addition to the screw connector 50, an actuating element 51 is connected to the second arm 49 of the external adjusting element 37 or its double-armed lever 41. The actuating element 51 is mounted together with the rotation axes 52, 53 of the double-armed levers 40, 41 on the upper part 34 of the inner plate 28 of the sliding beam 14. When the actuating element 51, which is designed as a spindle drive, for example, is rotated by a crank (not shown) placed on a spindle pin 52, for example, the arm 49 of the double-armed lever

41 is pivoted. This movement is transmitted via the screw connector 50 to the double-armed lever 40 of the adjusting element 36. Accordingly, the adjusting elements 36, 37 or their levers 40, 41 or screw connectors 38, 39 are adjusted synchronously at the same time, so that in the area of the inner plate 28

the entire lower part 32 with the base plate 30 attached to it is moved up or down relative to the upper part 34 or the base plate 24 of the main plank half 13. Thus, on one side, the sliding plank 14 can be adjusted in height relative to the main plank half 13 with just one adjustment process.

Just like the inner plate 28, the outer plate 27 also has an adjustment mechanism 35. Accordingly, by operating two actuating elements 51, the entire base plate 30 of the sliding plank 14 can be adjusted in height relative to the base plate 24 of the main plank 12 or main plank half 13.

To set the desired relative position between the sliding plank 14 and the main plank half 13 for the first time, the screw connectors 38, 39 of the adjustment mechanism 35 can be individually changed in their length. For this purpose, the screw connectors 38, 39 are designed as a turnbuckle or similar to a turnbuckle. The opposite ends 42, 44 and 43, 45 of the screw connectors 38, 39 are arranged so that they can be screwed together with the threaded sections 54 assigned to them in a common sleeve 55, a screw sleeve. The screw connector 50 is also designed so that its length is adjustable. After setting the appropriate length of the respective screw connector 38, 39, 50, i.e. after adjusting the distance between the opposite ends of the respective

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Screw connectors 38, 39, 50, the set length is secured by nuts 56 assigned to opposite ends of the sleeve 55, namely by lock nuts. After this setting of the desired relative position between the base plate 24 and the base plate 30 of the sliding screed 14 and the main screed half 13, the further up and down movement of the base plate 30 of the sliding screed 14 is carried out by actuating at least one actuating element 51.

&iacgr;&ogr; To further simplify the height adjustment, all adjustment elements 36, 37 of the respective sliding beam 14 - i.e. both the adjustment elements 36, 37 assigned to the inner plate 28 and the outer plate 27 - can be operated together. For this purpose, the opposing, outer double-armed

is lever 41 of the opposing adjustment mechanisms 35 of the outer plate 27 and inner plate 28 are connected to one another, namely by a shaft 57, which is designed as a torsion shaft. The shaft 57 therefore connects the opposing double-armed levers 41 of the adjustment elements 37 to one another. In deviation from this, it is also possible for the inner levers 40 to be connected to one another by a shaft 58 or for both levers 40, 41 to be connected to one another by one of the shafts 57, 58. The shaft 58 then connects the double-armed levers 40 of the opposing adjustment elements 36 to one another. In any case, only one adjustment mechanism 35, for example the inner plate 28, has an actuating element 51. By turning this actuating element 51, all four adjustment elements 36, 37 of the sliding beam 14 can then be adjusted simultaneously. The base plate 30 of the sliding beam 14 can therefore be adjusted in height with just one adjustment process.

The main plank half (not shown) is also assigned a sliding plank with the above adjustment mechanism.

According to Fig. 1, the outer plate 27 of the sliding beam 14 has a plate-shaped element 59, namely a side plate 60. The side plate 60 serves to form the edge of the floor covering 62 to be applied to a floor 61. The floor covering 62

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The floor covering 62 to be applied is guided by the side plate 60 in such a way that it does not swell away sideways. For this purpose, a predefined gap 63 must always be maintained between the floor 61 and the side plate 60 so that the lower edge of the side plate 60 does not touch the floor 61. To adjust this gap 63, the side plate 60 is mounted on the outer plate TJ of the sliding screed 14 so that it can move up and down. For this purpose, the side plate 60 is assigned an adjustment mechanism which is designed analogously to the adjustment mechanism 35 discussed in connection with Fig. 3. The adjustment mechanism 35 assigned to the side plate 60 is, however, adjustable independently of the adjustment mechanisms 35 assigned to the outer plate 27 and inner plate 28 of the sliding screed 14. It is also possible for only the main screed 12 to be assigned a side plate 60 with

is assigned to an adjustment mechanism 35. The same also applies to the main plank half (not shown) or the sliding plank possibly assigned to it.

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Applicant: Dynapac GmbH Ammerländer Str. 93

26203 Wardenburg

30 March 1995/8623 DPC-22-0E

Reference list :

10 Production direction 40 lever 11 Screed 41 lever 12 Main beam 42 End 13 Main plank half 43 End 14 Moving plank 44 End 15 Intermediate slide 45 End 16 End 46 poor 18 End plate 47 poor 19 Longitudinal center axis 48 poor 20 End 49 poor 22 End plate 50 Screw connectors 24 Base plate 51 Actuator 27 Outer plate 52 Rotary axes 28 Inner plate 53 Rotary axes 30 Base plate 54 Thread section 31 Bottom1 55 Sleeve 32 Bottom part 56 Mother 33 Top1 57 WeI Ie 34 Top1 58 WeI Ie 35 Adjustment mechanism 59 element 36 Adjust1 organ 60 Side plate 37 Adjust1 organ 61 Floor 38 Screw connectors 62 Flooring 39 Screw connectors 63 gap

Claims (11)

Expectations 1. Screed for a road surface finisher, with a main screed (12) arranged on the road surface finisher and preferably two sliding screeds (14) assigned to opposite ends (16) of the main screed (12), whereby the main screed (12) and each sliding screed (14) have at least one floor element (24, 30) and whereby at least the floor element (30) of the or each sliding screed (14) is designed to be movable up and down relative to the floor element (24) of the main screed (12) with the aid of several individually operable adjusting elements (36, 37), characterized in that at least two of the adjusting elements (36, 37) can be operated together. □PC22AN.DOC 2. Screed according to claim 1 ₁ , characterized in that side elements (27, 28) of each sliding screed (14) are each assigned two adjusting members (36, 37) operable in pairs. 3. Screed according to claim 1 or 2, characterized in that each adjusting member (36, 37) consists of a screw connector (38, 39) and a double-armed lever (40, 41), whereby one end (44, 45) of the screw connector (38, 39) is connected to an arm (46, 47) of the respective lever (40, 41). 4. Screed according to claim 3, characterized in that the two levers (40, 41) of each side element (27, 28) are coupled by a screw connector (50). 5. Screed according to claim 3 or 4, characterized in that a second end (42, 43) of the screw connector (38, 39) is connected to a lower part (31, 32) of the side element (27, 28) and that the lever (40, 41) is rotatably mounted on an upper part (33, 34) of the side element (27, 28) separate from the lower part (31, 32). 6. Screed according to one or more of claims 3 to 5, characterized in that second arms (48, 49) of the levers (40, 41) associated with a side element (27, 28) are connected to one another by a further screw connector (50), and that an actuating member (51) is associated with one of the second arms (49). 7. Screed according to one or more of claims 3 to 6, characterized in that the or each screw connector (38, 39, 50) is designed as a turnbuckle, the opposite ends (42, 44; 43, 45) of the turnbuckle with the threaded sections (54) assigned to them in are arranged screwably in a common sleeve (55). 8. Screed according to one or more of claims 1 to 7, characterized in that all adjusting elements (36, 37) of the sliding screed (14) can be operated together, whereby at least DPC22AN.DOC at least two opposite levers (40, 41) assigned to opposite side elements (27, 28) of the sliding beam (14) are connected to one another. s 9. Screed according to claim 8, characterized in that the levers (41) of the opposite side elements (27, 28) are connected to one another by a shaft (57) which forms an axis of rotation (53) for the interconnected levers (41). 10. Screed for a road surface finisher, with a main screed (12) arranged on the road surface finisher and preferably two sliding screeds (14) assigned to opposite ends (16) of the main screed (12), wherein the sliding screed ls len (14) or the main plank (12) have an outer side element (25), and wherein on the outer side element (25) a side plate (60) is arranged so as to be movable up and down with the aid of several individually operable adjusting elements, characterized in that the adjusting elements are designed so as to be operable in pairs or together. 11. Screed according to claim 10, characterized by an adjustment mechanism comprising two adjustment elements according to one or more of claims 2 to 9. DPC22AN.DOC ·* *··&idigr; *'