RU2266359C1 - Ballast removing chain for transportation of ballast bed crushed stone - Google Patents

Abstract

FIELD: railway transport.

SUBSTANCE: proposed chain consists of great number of articulated links 15 connected to each other and it is installed for rotation in plane arranged with tilting to plane of bed. It contains cross guide 9 being positioned on line of intersection of bed plane and plane of rotation at operation. Said serves to support chain and it is connected by guide joints 10 with longitudinal guides 12. Guide channel formed by longitudinal guide 12 and cross guide 9 has upper and lower sliding guides 17 passing parallel to plane of rotation and end face sliding guide 18 connecting longitudinal and cross guides and passing square to plane of rotation. End face sliding guide 18 of cross guide 9 is made curvilinear on end 11 adjoining longitudinal guide 12 in direction of guide joint 10 to form acute angle with extension of end face sliding guide 19 of longitudinal guide 12. To provide deflection of chain, contact between chain and end face sliding guide 18 is provided.

EFFECT: provision of chain improved serviceability without affecting articulated joints.

5 cl, 6 dwg

Description

The invention relates to a dredging chain for transporting crushed ballast bed, according to the signs given in the restrictive part of claim 1 of the formula.

From US 4614238, US 4014389 and DE 3151652 are already known similar, made endless, rotating around the path excavation chains. They consist mainly of a transverse rail in contact with the ballast bed and two longitudinal rails pivotally connected to it. Coaxially to the axis of the hinges, they are positioned along one bending roller, by means of which the extraction chain is deflected by at least 90 °. The articulation of the transverse and longitudinal guides is necessary because this creates the possibility of a slight displacement of the notch chain relative to the path. Thus, it is possible to work better in areas spatially limited, for example, by an apron. In addition, the swivel provides an extension of the transverse guide to clean the switch section. Since a tensile force of about 100 kN is applied to the extraction chain in powerful cleaning machines, the supply rollers supplied with sufficient lubrication are subject to maximum loads and must be replaced frequently.

The present invention is the creation of a generic excavation chain, which without deterioration of the hinge would provide its improved performance.

According to the invention, this problem is solved using a mining chain of the kind described above by means of the signs given in the characterizing part of claim 1 of the formula.

Thanks to this combination of features, it is possible to deflect the excavation chain even at high loads without worsening the articulation only due to sliding friction. Due to the special curvature of the end sliding guide, even in the case of a greater deviation of the longitudinal and transverse guides, it is possible to transfer the cutting chain to the longitudinal guide without problems. Thus, there is no need to use an envelope roller, which until now was considered by specialists to be inevitable in combination with a hinge. Due to the maximum load, this roller had to be made very high quality and, therefore, very expensive, and, in addition, equipped with a complex lubrication supply system.

Other advantages and implementations of the invention are given in the dependent clauses and in the drawings, where

figure 1 shows a side view of a cleaning machine with a dredging chain;

figure 2 is a simplified top view of the extraction chain;

figure 3, 4 is an enlarged top view of the deviation of the extraction chain;

5 is a section of a guide channel;

6 is a known deviation with a deflection roller.

The extraction chain 1 shown in FIG. 1 is located on the machine 2 for cleaning the ballast bed 3. During operation, the extraction chain 1 is located under the raised path 4 in the form of an endless chain passed around it. In this case, the contaminated crushed stone 5 is transported to the screening unit 6. The crushed stone 5 cleaned in it is again laid on path 4 in a manner known per se. The rotation of the extraction chain 1 occurs in the plane 7, which is inclined to the plane 8 of the bed. When the extraction chain 1 is in the cross-sectional plane of both planes 7, 8, a transverse guide 9 is positioned, passing across the ballast bed 3.

As can be seen in figure 2, the transverse guide 9 is pivotally connected by means of guiding hinges 10 at each curved end 11 with a longitudinal guide 12. Both longitudinal guides 12 form a transverse guide 9 with a transverse guide 9 (Fig. 5) for supporting and guiding the extraction chain 1 As indicated by the dot-dash line, the transverse guide 9 can be extended to pick up rubble in the arrow section.

As can be seen, in particular, in FIGS. 3 and 5, the extraction chain 1 consists of a plurality of links 15 interconnected by rollers 14. To guide the extraction chain 1, a guide channel 13 is used, consisting of the lower and upper sliding guides 17, as well as connecting them between each other end guide 18 of the slide. The latter runs perpendicular to the plane of rotation 7. The slideways 17, 18 are made of highly wear-resistant material and are detachably connected to the guide channel 13.

As can be seen, in particular in FIGS. 3 and 4, the sliding end guide 18 of the transverse guide 9 is curved in the form of an arc 19 of a circle in the direction of the guide hinge 10, so that the longitudinal guide 12 concludes with an extension of the end sliding guide 18 an acute angle α, preferably about 45 ° . Thus, a curved transverse guide end 20 of the end sliding guide 18 arises, which comes into contact with the notch chain 1 only when the angle between the longitudinal 12 and the transverse 9 guides changes, for example, in the case of the elongation of the transverse guide 9. The circular arc 19 has a center positioned on the axis 21 of the guide joint 10.

The distance a, limited by the adjacent longitudinal guide 12, on the one hand, and the hinge axis 21, on the other hand, and perpendicular to the sliding end guide 18 of the longitudinal guide 12, is identical to the radius r of the circular arc of the curved transverse guide end 20. The circular arc 19 forms a circular segment with angle β 60 °. The end sliding guide 18 has between the rectilinear segment 23 of the transverse guide 9 and the transverse guiding end 20 in the form of a circular arc a second segment 24 in the form of a circular arc, the center of which is positioned on a straight line 26 running parallel to the rectilinear segment 23 through the hinge axis 23.

Due to this particular embodiment of the end 20 of the transverse guide 9, the recess chain 1 can deviate without the help of the bending roller only due to sliding friction. The extraction chain 1 extends, for example, in a powerful cleaning machine with a pulling force of 110 kN in the direction of transportation indicated by the arrow in FIG. 3.

According to the known solution shown in FIG. 6, the withdrawal chain 1 deviates around the bending roller 27 mounted on the hinge axis 21 with the possibility of rotation and protruding through the hole of the end sliding guide 18 beyond its sliding plane. Thus, the grease-guided roller 27, in particular with a greater deviation between the longitudinal 12 and the transverse 9 guides, is subject to very high loads. In addition, the chain rollers 14 are subject to extreme loads.

Claims (5)

1. The extraction chain (1) for transporting crushed stone (5) of the ballast bed (3), consisting of a plurality of links (15) pivotally interconnected, the extraction chain (1) provided for rotation in the rotation plane (7) located with tilted to the bed plane (8), contains a transverse guide (9), which during operation is positioned on the line of intersection of the bed plane (8) and the rotation plane (7), is provided to support the extraction chain (1) and is connected by guiding joints (10) to longitudinal guides (12), moreover, formed by Along with (12) and transverse (9) guides, the guide channel (13) contains lower and upper rotations parallel to the plane (7), sliding guides (17), as well as connecting them to each other, running perpendicular to the plane (7) of rotation, end sliding guide (18), characterized in that the end sliding guide (18) of the transverse guide (9) at its end (11) adjacent to the longitudinal guide (12) is curved in the direction of the guide hinge (10) so that it concludes with lengthening t the front sliding guide (18) of the longitudinal guide (12) has an acute angle α, moreover, to deflect the extraction chain (1), contact is exclusively provided between the extraction chain (1) and the end sliding guide (18). 2. The chain according to claim 1, characterized in that the end sliding guide (18) of the end (11) of the transverse guide (9) is curved in the form of an arc (19) of a circle with a center located on the axis (21) of the adjacent guide joint (10) . 3. The chain according to claim 2, characterized in that the distance (a) limited by the adjacent longitudinal guide (12) on the one hand and the hinge axis (21) on the other hand and extending perpendicular to the end guide (18) of sliding the longitudinal guide (12) , identical to the radius (r) of the arc (19) of the circle. 4. The chain according to claim 2, characterized in that the arc (19) of the circumference of the end (11) of the transverse guide (9) forms a circular segment with an axis (21) of the hinge with an angle β = 60 °. 5. The chain according to one of claims 1 to 4, characterized in that the end guide (18) of sliding has between the straight segment (23) of the transverse guide (9) and the end (11) in the form of an arc of a circle, the second segment (24) in the form an arc of a circle whose center is positioned on a straight line (26) passing parallel to a rectilinear segment (23) through the axis (21) of the hinge.

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