EP0501318A1 - Transport waggon - Google Patents

Abstract

Rail-bound transport waggon (1) having a machine frame (3) supported on rail bogies (2) and a floor conveyor belt (4) which extends in the longitudinal direction of the waggon, is arranged above the machine frame (3) and is inclined with respect to the track plane forming a lower receiving end (8) and a higher discharge end (9). Said belt is assigned side walls (6) which extend parallel with one another in order to laterally bound and form a storage space. The discharge end (9) of the floor conveyor belt (4) is constructed so as to be displaceable transversely with respect to the longitudinal direction of the waggon in relation to the rail bogie (2) located at this end by means of a transverse displacement drive (13). <IMAGE>

Description

The invention relates to a rail-bound transport wagon with a machine frame supported on rail bogies and a floor conveyor belt running in the longitudinal direction of the wagon, arranged above the machine frame and inclined with respect to the track plane with the formation of a lower receiving end and a higher ejecting end, which parallel to one another for lateral limitation and formation of a storage space running sidewalls are assigned.

Such a trolley is already known from EP-A 2 0 368 046. The higher and in the conveying direction front end or discharge area of the floor conveyor belt is designed to protrude beyond the end of the machine frame, so that the discharge side end of the floor conveyor belt comes to lie above a lower end or reception area of a further transport carriage. In this way, with any number of transport wagons connected to one another in a train, a continuous transport of bulk goods is possible, each with an automatic unloading and loading. In order to achieve a corresponding dumping height for the maximum storage of bulk material, the height difference of the floor conveyor belt between the receiving end and the discharge end is essentially equal to the inside wall height of the side walls. In such a known transport trolley, however, problems arise with regard to a proper transfer of material from the higher discharge end to the lower upstream receiving end, since the higher discharge end is moved to a greater extent by the projecting arrangement away from the middle of the track.

The object of the present invention is to create a transport carriage of the type described in the introduction, with which it is also possible to transfer bulk goods to a further transport carriage located upstream in the direction of transport, even in track bends.

This object is achieved in that the floor conveyor is at least in one of its two ends with respect to the rail carriage located in this end by a transverse shift drive transverse to the longitudinal direction of the carriage. With this solution, there is the possibility of shifting an end region of the floor conveyor belt relative to the middle of the track so far in a direction transverse to the longitudinal direction of the wagon or track that an overlapping arrangement of a dropping end of a first transport wagon over the receiving end of a second also in track arches Transport trolley is ensured. With a corresponding further transverse displacement of the floor conveyor belt, it is always possible to transfer the bulk material in an advantageous manner, even in curved tracks with a relatively small radius. In addition, the transverse displacement also eliminates the problems occurring in the curve of the track due to the transverse inclination of the track, according to which the bulk material dropped in the middle from the higher throwing end hits off center along a vertical fall line on the lower receiving end. By means of a corresponding transverse displacement of the dropping end, corrective intervention can now be carried out until the dropped bulk material strikes the receiving end in the middle despite the transverse inclination.

The embodiment according to claim 2 has the advantage that the discharge area located higher up and due to its projecting arrangement in track arches is located particularly strongly outside the middle of the track can be centered exactly above the rear receiving area of the floor conveyor belt, which is unchanged on the track center.

The design according to claims 3 and 4 ensures problem-free transverse displacement of the floor conveyor belt with constant secure support on the machine frame.

The variant characterized in claim 5 results in a structurally particularly simple and stable solution for a problem-free transverse displacement of the higher discharge area of the floor conveyor belt.

The development according to claim 6 enables a problem-free transmission of the thrust forces effective due to the inclination of the floor conveyor belt in its longitudinal direction to the machine frame without impairing the displaceability.

A further development according to claim 7 enables a transverse displacement of the floor conveyor belt together with the machine frame relative to the track either in connection with the previously mentioned transverse displacement of the floor conveyor belt relative to the machine frame or without this solution. A centering of the projecting discharge area of the floor conveyor belt, which is independent of track arches, is thus also possible for an unimpeded transfer of the bulk material to a further floor conveyor belt following in the transport direction.

With the sliding wall mentioned in claims 8 and 9 there is an unimpeded transverse movement of the projecting discharge area resulting from the deflection in track arches for transfer journeys of the floor conveyor belt possible.

The embodiment according to claim 10 enables an optimal height adjustment of the floor conveyor belt depending on the desired dumping height. If, for example, floor conveyor belts arranged in series are used only for the transport of bulk material, a lowering of the floor conveyor belts with respect to the machine frame is possible. Only when the bulk material is stored, only the bottom conveyor belt in the transport direction has to be raised in order to form a desired bulk height in the transfer area.

The embodiment according to claim 11 enables an advantageous height adjustment of the floor conveyor belt in its higher end region, so that it can be quickly adjusted from a working position that exceeds the clearance profile without conversion work into a transfer position located within the clearance profile. The combination of a vertical and transverse displacement drive according to claim 12, the advantages mentioned can be achieved with regard to a proper transfer of the bulk material, which is also secured in track bends, and a positioning of the floor conveyor belt outside the clearance profile, which is limited to the work involved.

The design according to claims 13 and 14 allows for a structurally very simple design of the support frame, an optional combination of the height adjustment with the transverse displacement, wherein a secure support of the floor conveyor belt on the machine frame is guaranteed in each adjustment position.

The support of the rear, lower receiving area characterized by claim 15 ensures on the one hand a stable mounting of the floor conveyor belt on the machine frame and on the other hand also enables unimpeded height and transverse adjustment of the higher discharging area.

The invention is described in more detail below with reference to exemplary embodiments shown in the drawing.

• Fig. 1 eine Seitenansicht eines erfindungsgemäß ausgebildeten Transportwagens mit einem in seinem Abwurfbereich angehobenen, durchgehend ausgebildeten Bodenförderband,
• Fig. 2 eine Seitenansicht des Transportwagens gemäß Fig. 1, wobei jedoch das Bodenförderband im Bereich des Abwurfendes für die Überstellposition abgesenkt ist,
• Fig. 3 eine vergrößerte Seitenansicht eines Stützrahmens zum Abstützen und Höhenverstellen des Bodenförderbandes.
• Fig. 4 eine Ansicht des Stützrahmens und Bodenförderbandes gemäß Pfeil IV in Fig. 3,
• Fig. 5 eine vergrößerte Seitenansicht des in Transportrichtung hinteren Aufnahmeendes des Transportwagens und
• Fig. 6 eine schematische Draufsicht auf zwei Transportwagen in einem Gleisbogen und
• Fig. 7 ein weiteres Ausführungsbeispiel eines Transportwagens mit einem querverschiebbaren Schienenfahrwerk.

Show it:

• 1 is a side view of a transport trolley designed according to the invention with a continuous floor conveyor belt raised in its discharge area,
• FIG. 2 shows a side view of the transport trolley according to FIG. 1, but with the floor conveyor belt lowered in the region of the discharge end for the transfer position,
• Fig. 3 is an enlarged side view of a support frame for supporting and adjusting the height of the floor conveyor belt.
• 4 is a view of the support frame and floor conveyor belt according to arrow IV in FIG. 3,
• Fig. 5 is an enlarged side view of the rear receiving end of the trolley in the transport direction and
• Fig. 6 is a schematic plan view of two transport cars in a track and
• Fig. 7 shows another embodiment of a transport carriage with a cross-slide rail chassis.

1 and 2 consists essentially of a machine frame 3 supported on rail carriages 2 and a floor conveyor belt 4 running in the longitudinal direction of the carriage. This is mounted in a support frame 5 which is connected to two side walls 6 running parallel to one another and in the longitudinal direction of the carriage is. The floor conveyor belt 4, which has a drive 7 with a variable rotational speed, is inclined to form a lower receiving end 8 and a higher-lying discharge end 9 with respect to the machine frame 3. The transport direction of the floor conveyor belt 4 is indicated by an arrow 10. The higher discharge end 9 of the floor conveyor belt 4 projects beyond the front end of the machine frame 3 in such a way that the dropped bulk material falls onto the reception end 8 of a further coupled transport carriage 1. In the area of the higher discharge end 9 of the floor conveyor belt 4, rails 11 are arranged on the machine frame 3 and extend transversely to the longitudinal direction of the carriage to support a support frame 12 connected to the support frame 5 or floor conveyor belt 4. The support frame is connected to a transverse displacement drive 13 as well as to a height adjustment drive 14. The energy required for the various drives is supplied by an internal combustion engine 15. The lower receiving end 8 of the floor conveyor belt 4 is mounted on a turntable or a support 17 which can be rotated about a vertical axis 16. The one with the floor conveyor 4 connected support frame 5 is additionally attached to said support 17 so as to be pivotable about an axis 18 extending transversely to the longitudinal direction of the carriage.

A section of each side wall 6 located in the lower-lying receiving end 8 of the floor conveyor belt 4 is formed by a sliding wall 19 which can be moved parallel to the side wall plane in the longitudinal direction of the carriage.

The floor conveyor belt 4 shown in FIG. 2 is in a lowered position for transfer travel by appropriately loading the height adjustment drive 14, in which in particular the upper edges of the side walls are arranged in the region of the discharge end 9 within the prescribed clearance profile. The two sliding walls 19 are in an advanced position so that the ejecting end 9 of the downstream floor conveyor belt 4 can perform an unhindered deflection movement in curved tracks.

The support frame 12 shown enlarged in FIG. 3 has two support beams 20 which run parallel to one another in the longitudinal direction of the carriage and are inclined to the plane of the machine frame 3, the lower ends of which are articulated to the support frame 12 and the higher ends of which are connected to flange rollers 21. These are slidably mounted in the plane of the floor conveyor belt 4 in the support frame 5. A horizontal support frame 22, which is connected to the height adjustment and transverse displacement drive 13, 14 and to the two support supports 20, can be supported by four flanged rollers 23 on the two rails 11 running transversely to the longitudinal direction of the carriage.

As can be seen in FIG. 4, the support frame was displaced transversely with respect to the center of the machine frame 3 by acting on the transverse displacement drive 13 connected to the machine frame 3 together with the height adjustment drives 14, the support frame 5 and the conveyor belt 4 and the side walls 6. This transverse displacement can - depending on the radius of the curvature of the track - be carried out independently of the height adjustment of the floor conveyor belt 4 by the two height adjustment drives 14 and also independently of the transport of the bulk material.

The sliding wall 19, shown enlarged in FIG. 5, is mounted on rollers 24 and can be displaced by means of a displacement drive 25 from a rear working position shown in full lines to a front transfer position shown in dash-dotted lines.

6 that the projecting discharge end 9 of the right floor conveyor belt 4 is arranged offset in the middle with respect to the machine frame 3 shown with solid lines. This also ensures in track arches (represented by a track axis 26) that the discharge end 9 comes to lie above the upstream receiving end 8 of a further floor conveyor belt 4.

The mode of operation of the trolley according to the invention is described in more detail below.
The floor conveyor belts 4 of a loading train formed from a plurality of coupled transport carriages 1 are in the lowered transfer position shown in FIG. 2 during the transfer journey to the construction site. The sliding walls 19 are each in their front end position, so that the projecting throwing ends 9 can be moved freely in track arches. In the track construction site, for example, a cleaning machine throws overburden onto the rearmost floor conveyor belt 4 (see Fig. 1). When the various drives 7 for the individual floor conveyor belts 4 are put into operation, the bulk material is transported from the rear to the front transport carriage 1 to the foremost carriage of the loading train, each being transferred. The floor conveyor belt 4 of the car located immediately behind the foremost transport car 1 is raised by acting on the height adjustment drives 14, so that the storage space formed by the side walls 6 of the foremost transport car 1 is filled to form a corresponding dumping height. Simultaneously with the lifting, the two sliding walls 19 of the foremost transport carriage 1 storing the bulk material are moved into the rear end position (see FIGS. 1 and 5).

As soon as the loading train enters a track curve as part of the continuous work priority while storing, the higher and protruding discharge end 9 of each transport carriage 1 is moved under the action of the respective transverse shifting drive 13 until the respective discharge end 9 is exactly in the middle above the upstream reception end 8 of the upstream transport carriage 1. This control can also be carried out automatically, for example, by corresponding limit switches mounted on the sliding walls 19 and contacting the discharge end 9. The loading is carried out in such a way that no bulk material is stored in the area of the sliding walls 19. To fill up the second transport carriage 1, the floor conveyor belt 4 of the first carriage can be lowered, while the downstream floor conveyor belt 4 is raised in order to achieve a corresponding dumping height. In this way - starting with the first, foremost transport carriage - all transport carriages 1 are successively filled up. Deviating from the solution described, it is of course also possible, for example that to design the rear, lower-lying receiving end 8 with the aid of a transverse displacement drive so that it can be displaced relative to the machine frame, while the front, higher-lying discharge end cannot be displaced transversely. With a corresponding transverse adjustment of the receiving end, unimpeded material transfer from the upstream transport wagon can also take place in track bends.

A transport carriage shown in FIG. 7 with a continuous floor conveyor belt 27, with side walls 28 and a machine frame 29 has a rail carriage 30 which can be displaced transversely with respect thereto. This is mounted in a transverse guide 31 fastened to the underside of the machine frame 29 and connected to a transverse displacement drive 32. With a transport trolley of this type - in order to ensure an orderly transfer of material from the projecting drop to the upstream receiving end in track bends - the drop end together with the machine frame 29 can be shifted with respect to the middle of the track. In addition, there is also the possibility of adjusting the height of the floor conveyor belt 27 relative to the machine frame 29 by arranging appropriate height adjustment drives.

Claims (15)

Rail-bound transport wagon with a machine frame supported on rail bogies and a floor conveyor belt running in the longitudinal direction of the wagon, arranged above the machine frame and inclined with respect to the track level to form a lower-lying receiving end and a higher-lying throwing-off end, to which side walls which run parallel to one another to limit and form a storage space are assigned , characterized in that the floor conveyor belt (4; 27) at least in one of its two ends (8,9) with respect to the rail undercarriage (2; 30) located in this end is designed to be displaceable transversely to the longitudinal direction of the wagon by means of a transverse slide drive (13; 32) is. Trolley according to claim 1, characterized in that the higher-lying discharge end (9) of the floor conveyor belt (4) is designed to be displaceable transversely and the rear, lower-lying receiving end (8) of the floor conveyor belt (4) by a perpendicular to this or to the plane of the machine frame (3 ) extending axis (16) is rotatably mounted on the machine frame (3). Trolley according to claim 1 or 2, characterized in that in the higher discharge end (9) of the floor conveyor belt (4) a rail (11) attached to the machine frame (3) and extending transversely to the longitudinal direction of the trolley for supporting a support frame connected to the floor conveyor belt (4) (12) is arranged. Carriage according to Claim 3, characterized in that the support frame (12) connected to the floor conveyor belt (4) is supported on two rails (11) which run transversely to the longitudinal direction of the carriage and parallel to one another and which are in the same position with respect to a pivot pin of the rail carriage (2) located underneath Distances are distant. Carriage according to one of claims 1 to 3, characterized in that the support frame (12) is designed as a flange (23) for supporting slides on the rails (11) and is connected to the transverse slide drive (13) articulated on the machine frame (3). Trolley according to one of claims 1 to 5, characterized in that the rear, lower-lying receiving end (8) of the floor conveyor belt (4) is mounted on a turntable (17) which can be rotated about a vertical axis (16). Carriage according to one of claims 1 to 6, characterized in that at least one of the rail carriages (30) is mounted on the machine frame (29) so as to be displaceable in a direction perpendicular to the longitudinal direction of the carriage and is connected to the transverse displacement drive (32). Carriage according to one of claims 1 to 7, characterized in that a section of each side wall (6) located in the lower receiving end (8) of the floor conveyor belt (4) is formed by a sliding wall (19) which can be displaced parallel to the side wall plane in the longitudinal direction of the carriage. Carriage according to claim 8, characterized in that each sliding wall (19) is connected to a sliding drive (25). Trolley according to one of Claims 1 to 9, characterized in that the floor conveyor belt (4) is designed to be height-adjustable in relation to the machine frame (3) by means of a height adjustment drive (14). Carriage according to claim 10, characterized in that the height adjustment drive (14) is arranged in the region of the discharge end (9) of the floor conveyor belt (4) projecting beyond the machine frame (3), that in the opposite receiving end (8) around a transversely to the carriage longitudinal direction Axis (18) is pivotally mounted on the machine frame (3). Carriage according to one of claims 1 to 11, characterized in that the height adjustment drive (14) is arranged between the floor conveyor belt (4) and the support frame (12) designed as a cross-slide. Carriage according to claim 12, characterized in that the support frame (12) mounted on rails (11) so as to be displaceable transversely is connected to two support supports (20) which run parallel to one another in the longitudinal direction of the carriage and are inclined to the plane of the machine frame (3) and whose lower ends are articulated are connected to the support frame (12) and the higher ends thereof with flange rollers (21). Carriage according to one of claims 10 to 13, characterized in that the flange rollers (21) connected to the support beam (20) on the support frame (5) in whose longitudinal direction is slidably mounted. Carriage according to one of claims 1 to 14, characterized in that the receiving end (8) of the floor conveyor belt (4), which is further distanced from the height adjustment drives (14), is pivotably mounted on a support (17) about an axis (18) running transversely to the longitudinal direction of the carriage , The support (17) itself being mounted on the machine frame (3) so as to be rotatable about a vertical axis (16).

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