RU94629U1 - SECTION OF THE SHIELD MECHANIZED MOUNT FOR MOUNTAINS, AS WELL AS THE SWINGING LEVER AND THE BASIS OF THE SECTION FOR IT - Google Patents

Abstract

 1. The section of the shield mechanized lining for underground mining with two bases (50; 150) sections and four swinging levers (20; 30) to create a lever mechanism (2), of which two swinging levers (20) form the front swinging levers, which accordingly, with the help of the front pivot pin (5), the sections are rotatably mounted on the base (50; 150), and of which two swinging arms form the rear swinging arms, which are respectively mounted on the base (50; 150) of the section with the possibility of rotation by means of the rear pivot pin (8), and each swinging lever (20; 30) has two longitudinal struts (21, 31), which at their ends in the form of the lower as well as the upper fork joints (23, 24; 33, 34) protrude the middle jumper (22; 32), rigidly connecting the longitudinal struts, and each base (50; 150) of the section has a middle block (51; 151) with front and rear holes (161; 162) for pivoting fingers, and on the sides of the middle block (51; 151) side flaps (54; 154), characterized in that at least the middle jumpers (22; 282) of the front swing arms (20; 220) are spaced apart from the lower fork joints (23; by their front side (25; 285); 223) front swing levers (20; 220) with the formation of vertical passages (2 6; 28 6) for the broken rock and / or that the bases (50; 150) of the section are equipped with inclined bottoms (53; 153) to lead the broken rock to the side. ! 2. Section according to claim 1, characterized in that the middle jumpers (32) of the rear levers (30) with their front side (35) are separated from the lower fork hinges (33) of the rear levers (30) with the formation of vertical passages (36) for the broken breed. ! 3. Section according to claim 1, characterized in �

Description

2420-161124RU / 018

SECTION OF THE SHIELD MECHANIZED MOUNT FOR MOUNTAINS, AS WELL AS THE SWINGING LEVER AND THE BASIS OF THE SECTION FOR IT

The invention relates to a section of mechanized shield support for underground mining with two section bases and four swinging levers to create a lever mechanism for the articulated support of the block fence, of which two swinging levers form the front swinging levers, which, respectively, are installed with the help of the front rotary finger based on the section with the possibility of rotation, of which two swinging arms form the rear swinging arms, which, respectively, are installed between a rear swivel finger on the base of the section with the possibility of rotation, and each swinging lever contains two longitudinal struts, which with their ends in the form of lower and upper fork hinges protrude beyond the middle jumper, rigidly connecting these longitudinal struts, and each base section contains a middle block with front and rear holes for the rotary fingers, and side shields on the sides of the middle block. In addition, the utility model relates to a swinging arm of a section of a shield mechanized roof support with two longitudinal struts, which with their ends in the form of a lower and upper fork hinges for installing a swinging arm with the possibility of rotation on the base of the section by means of pivoting fingers protrude behind the middle jumper rigidly connecting them, as well as to the base of the section of the shield mechanized roof support with the middle block, on which the front hole for the finger for installing the front swing arm and the rear from a finger hole for installing the rear lever, for example, a four-link mechanism for supporting the block fence, and side shields are installed on both sides of it.

The applicant uses in the underground mining sections of the shield mechanized roof support with similar swinging levers and similar base sections for various formation capacities and heights of the working face. So that the shield supports during cleaning operations, regardless of the current height of the working face, can support the working face between the so-called lying side, on which the base of the section is located, and the so-called hanging side, to which the upper rod is pressed using the lever mechanism and hydraulic spacers, the distance between the base of the section and the upper should change regularly and smoothly until both extreme positions are reached. A particular problem in this case is the working faces of small heights or with a small thickness of the formation, since in this case not only mining machines with low penetration should be used, but also the shield support sections should, if necessary, be folded into their most lowered position. In this state, the hydraulic struts are fully retracted, and the front and rear levers are located almost parallel to the lying side.

To achieve the lowest lowered position, efforts are already being made to either prevent the accumulation of collapsed rock in the sinus between the base of the section and the corresponding lever, or to use control devices that detect accumulations of pieces of rock so that the miner can then remove them. For automatic extrusion of broken rock when lowering the levers from DE 8210762 U1 it is known, for example, to install a foam pillow along with flat steel springs in the sinus between the lever and the base of the section. DE 202005007725 U1 proposes to equip the levers with a guard as a protective device, which is to prevent penetration of broken rock into the sinus, and from DE 202004007635 it is known to install a sinus control sensor on a hydraulic strut.

The objective of the utility model is that in the case of a section of mechanized shield support for underground mining using structural measures related to the swing arm or the base of the section, minimize the risk of blocking swing arms when folding the lever mechanism.

This, as well as other tasks according to the utility model, are solved in the case of a panel of a mechanized roof support due to the fact that at least the middle bridges of the front swinging arms with their front side are separated from the lower fork joints of the front swinging arms with the formation of vertical passages for broken rock and / or that the base of the section is equipped with inclined bottoms to lead the broken rock to the side (side). Both proposed measures are based on the fact that the accumulation of broken rock in the sinus due to collapsed rock, coal, etc. impossible to completely prevent. Structurally specified vertical passages for the broken rock between the fork hinge and, therefore, the pivot pin, and the front side of the middle bridge make sure that even the collapsed rock accumulated in the bosom cannot prevent the levers from lowering to the lowest position, since this rock material when lowering (sliding ) may be pushed up through the passages for broken rock. It is clear that for this the passages for the broken rock must be of sufficient size. However, for the stable and rigid embodiment of the swinging arms alone, it is sufficient that both longitudinal struts are welded to each other only on a part of their length, and not along their entire length, as has so far been accepted in accordance with the prior art. The second measure, which can be provided as an alternative or in addition to vertical passages for broken rock, is reduced to inclined bottoms between the middle block and the side shields of the base of the section in order to prevent the accumulation of collapsed rock in the bosom due to the fact that it can slip in side and thus cannot accumulate under the levers, in particular the front levers.

In the case of a shield support section, it may be sufficient that only the front swing arms are provided with appropriate vertical passages for the broken rock. However, in particular, in one preferred embodiment, the middle bridges of the rear levers with their front side are spaced from the lower forks of the rear swing arms to form or create vertical passages for the broken rock.

The swing levers for the shield support section according to the utility model for solving the above problem are characterized in that the middle bridge with its front side is spaced from the lower fork hinge with the formation of at least one vertical passage for the broken rock, so that the broken rock through the vertical passage or vertical the passages for the broken rock could be pushed up when the swinging lever or lever mechanism, as a result of lowering the hydraulic supports, rotates in a substantially horizontal ntalnoe position.

In order to achieve sufficiently large vertical passages for the broken rock, without at the same time endangering the necessary stability of the swinging arms, the vertical passages for the broken rock can pass at least 25%, preferably about 30-50% of the length of the levers between their pivoting fingers . As a rule, it is sufficient to provide vertical passages for the broken rock essentially only at the lower fork joints or hinge holes located on the side of the base of the section, since there is a sinus that is dangerous from the point of view of blocking. For this, one single continuous or continuous, vertical passage for the broken rock from the lower fork hinge to the front side of the middle lintel can be provided. Alternatively, the middle bridge may also consist of several elements of the middle bridge, in particular two elements, the first vertical passage for the broken rock, and preferably between the elements of the middle bridge, between the front side of the middle bridge element closest to the lower fork hinge and the fork joint at least one other vertical passage is made for the broken rock. True, as a result of this measure, the vertical passage for the broken rock located near the forked joint is smaller than in the previous embodiment with one single vertical passage for the broken rock. However, due to the additional connecting element between the longitudinal struts, the strength of the lever and its ultimate bending strength are simultaneously increased. It is particularly preferred that the middle web element adjacent to the lower fork hinge has a groove or recess on its front side. In addition, the element of the middle bridge, located next to the lower fork hinge, for better removal of the broken rock in the direction of the vertical passages for the broken rock on its lower side can be made wedge-shaped. As an alternative or addition, the element of the middle bridge located adjacent to the lower fork hinge can extend essentially only to half the depth of the longitudinal supports, i.e. with an interval from the lower side of the levers, and thereby increase the free space located on the side of the base section, while increasing the strength of the levers in bending.

The middle bridge or the middle bridge elements connecting the connecting longitudinal struts can be made in the form of solid blocks or hollow boxes, or a component of a hollow middle box or element of the middle box welded between the longitudinal struts.

In one particularly preferred embodiment, the shield support sections or the swing arms, in particular the front swing arms, the shield support sections, the longitudinal struts on the lower sides are provided with displacement bevels. The displacement bevels, in particular, may be bevels on the corresponding outer edge of the longitudinal struts. The bevels preferably extend substantially along the entire length of the front arms between the fork joints, and they preferably interact with the inclined bottoms, creating a kind of knife-like effect when the front arms are turned down. The knife effect can further push the broken rock out and thereby in the direction of the inclined bottoms descending outward and downward. In addition, preferably, they can have a bevel on the lower side and the front sides of the middle jumpers. The bevels on the lower sides of the struts to achieve a relatively good displacement of the broken rock may have an angle of preferably about 45 °. Other bevel angles can have the same effect.

The task set above, in the case of the base of the section for the section of the shield mechanized lining, is solved by the fact that between the at least one of the side shields and the middle block there is an inclined bottom for taking the broken rock to the side (side). Depending on the embodiment of the base of the section, it may be sufficient that the inclined bottom provides abduction of the broken rock from only one side. However, it is particularly preferable that at the base of the section or at the section of the shield support with the corresponding base of the section, between the middle block and both side flaps, respectively, an inclined bottom is located or formed, so that a corresponding inclined bottom descends (descends) from the middle block to the side flap .

In one embodiment, the side flaps may be provided with grooved or recessed windows like side passages for the broken rock, the inclined bottoms preferably terminating at the lower edge of the groove so that the collapsed rock sliding sideways along the inclined bottom can retract or push out through the side shields. In an alternative embodiment, the side flaps between the front and rear hinges of the connecting or pivot pin may be provided with a lowered contour having an upper edge of the side flap in the direction of which the inclined bottoms descend, preferably continuously. By side shields with a lowered contour are meant those of them in which the upper edge ends essentially at the level of the inclined bottom. Moreover, in a preferred embodiment, the upper edge of the side flap may extend partially at the same level with the pivot axis of the rear pivot pin or below it.

In one of the embodiments, the base sections can be made between the middle block and the side flaps in the form of a box-shaped structure, and the inclined bottoms consist of only boxes with a triangular cross section, in turn, mounted on the lower boxes, etc. As an alternative to the base, the sections may comprise continuous intermediate beams between the middle block and the side flaps, the upper sides of which are beveled and thereby form continuous (not hollow) inclined bottoms. The intermediate beams may also contain inclined bottoms in the form of a bath. Combinations of these or a layered structure of intermediate beams are also possible.

Preferably, in the side shields, as is known per se, installation means for finger stops are respectively made, for example, at two base sections on the side shields facing each other, the finger stops can be mounted rigidly or integrally with the side shields, while dismountable finger stops are located only on the respective outer side shields.

Other advantages and embodiments of the shield support section according to the utility model with swing arms and / or base sections made according to the utility model follow from the following description of exemplary embodiments schematically shown in the drawings, as well as from the dependent claims of the utility model. In the drawings:

figure 1 is a schematic side view of a section of a shield lining with the base of the section linking a four-link mechanism and a blocking fence;

figure 2 is a top view of the two bases of the section of the shield support with mounted front and rear swinging levers;

figure 3 is a section along the line III-III in figure 1 without an obstruction;

4 is a side view of a front swing arm according to a utility model;

5 is a top view of the base of the section in perspective according to the second embodiment;

6 is a side view of the base of the section of figure 5;

Fig.7 is a section along the line VII-VII in Fig.6;

Fig. 8 is a side view of a front swing arm according to a utility model in accordance with a second embodiment, in partial section; and

Fig.9 is a top view of the swing arm in Fig.8.

1 schematically depicts a section of a shield mechanized lining, indicated generally by the position 10. By itself, in a known manner, the section 10 of the shield lining contains two bases 50 sections, of which figure 1 shows only one, and on each base 50 are installed with the possibility of rotation, respectively, the front swing arm 20 and the rear swing arm 30 of the four-link mechanism 2. Using the front levers 20 and the rear levers 30 of the four-link mechanism 2 with rotation, in turn, under a blocking fence 3 is supported, at the upper end of which a power joint 4 of the upper arm is made so that the upper arm not shown there is articulated there, which, in turn, is supported with respect to the bases 50 of the section and can be moved vertically, as well as limitedly and horizontally so as to leave free underground lava between the bases of section 50 and the upper section not shown when cleaning for an underground mining installation. Figure 1 shows a section 10 of the shield support in a position in which the block fence 3 has not yet reached its lowest folded position, since both the front levers 20 and the rear levers 30, as a result of folding (pushing) the hydraulic struts can fall even further clockwise. The designations “front” for the front arm 20 and “rear” for the rear arm 30 refer to the operation mode of the shield support section 10, in which the mining machine moves along the underground face, while the roof (hanging side) collapses behind the block fence 3 and the falling rock locks the already cleared face. Therefore, the front levers 20, made longer than the rear levers 30, are located closer to the working face and, therefore, in front.

For the shield support section 10, the front levers 20, as shown also in FIG. 2, are mounted in the front connecting hinge 6 with the front pivot pin 5, and the rear levers 30, with the help of the second pivot pin 7, are installed in the rear connecting hinge 8 on the basis of the section 50 moreover, the pivot pin 5 and the connecting hinge 6 are located above the rear pivot pin 7 and, accordingly, the connecting hinge 8. In front of the connecting hinge 6 with the pivot pin 5 for the front arm 20, a hinge bath 9 is installed for the hinged installation the hemispherical connecting bottom of the not shown strut for sliding and folding section 10 of the shield support. Both the front lever 20 and the rear lever 30 are relatively wide and have two longitudinal longitudinal struts 21, 31, here they are motionless and rigidly bent to be connected to each other by means of a single middle bridge 22 and 32 formed by a hollow (middle) box, respectively, extending substantially along the entire depth of the longitudinal struts 21. The middle lintels 22, 32 welded to both longitudinal struts 21 and 31, respectively, pass through circumferential welds, as is especially clearly seen in FIGS. 1 and 2, only approximately 45% of the length of the longitudinal struts 21, 31 of the swinging arms 20, 30 between the lower fork joints 23 and 33, respectively, and the upper fork joints 24, 34, which make up the swivel joint with the block fence 3. As the middle bridge 22 of the front lever 20, and the middle jumper 32 of the rear lever 30, have, therefore, the front sides 25 and 35, respectively, spaced from the corresponding lower fork hinge 23 and 33 at a fairly large distance with the formation of an elongated vertical passage for the broken rock. As shown in the top view of FIG. 2, both passages 26 and 36 for the broken rock between the respective longitudinal struts 21 and 31 of the levers 20, 30 extend almost in half of their total length. Due to the vertical passages 26, 36 for the broken rock when folding section 10 of the shield lining, i.e. when lowering the levers 20, 30 of the four-link mechanism 2 in the direction of the section base 50, if necessary, the broken or collapsed rock collected through the passages 26 and 36 for the broken rock can be pushed up and thus can not cause any blockage when the four-link mechanism 2 is folded Both the front levers 20 and the rear levers 30, however, can be made relatively wide and thereby obtain suitable cross sections for reliable support of the block fence 3 and the upper without impairing the binding mode of folding the four-link mechanism 2 because of this enhanced performance levers 20, 30.

Reference is now made to FIG. 4, in which the front arm 20 is shown in detail in partial section. Only both longitudinal struts 21 of the front arm 20 capture its entire length, both longitudinal struts 21 ending integrally in the lower fork hinge 23 and the upper fork hinge 24 with the corresponding swivel pin holes 23A and 24A. While both longitudinal struts 21 consist of a continuous strip of metal, the middle bridge 22 is made in the form of a hollow or box-shaped profile with a relatively small thickness wall curved around the perimeter made of a metal sheet. The middle jumper formed by the middle box 22 is welded around the perimeter to both longitudinal struts 21. In the side view of Fig. 4 it is clearly seen that the front side 25 of the middle jumper 22 is at some distance from the pivot axis 5 'of the lower fork hinge 23, approximately corresponding half the distance between the rotary axis 5 'in the lower fork joint 23 and the rotary axis 24' in the upper fork joint 24. Due to this, the collapsed rock, if it is collected in the bosom between the base of the section and the front lever, can withdraw upward between two longitudinal struts 21 approximately half the length of the front arm 20.

In addition, both longitudinal struts 21 essentially along the entire partial length between the two forked hinges 23, 24 on the lower side 21 'of the struts have a bevel 27, and this bevel, respectively, forms the outer edge of both longitudinal struts 21. This is especially noticeable in FIG. .3 to which reference refers.

In Fig. 3, the front arm 20 is shown in the sectional plane shown in Fig. 1, so that, based on the presented sectional image, both longitudinal struts 21 extend to the corresponding connecting hinge on the basis of the section 50. Since the sectional plane in FIG. 3 extends in front of the very front side 25 of the middle web 22, a vertical passage 26 is also visible for the broken rock between both longitudinal struts 21. On the lower sides 21 'of the longitudinal struts, in turn, respectively, the bevels are clearly visible 27 on the outer edges of the longitudinal struts 21, wherein both bevels 27 form the bevels of displacement and here have a bevel angle relative to the lower side 21 'of the struts of about 45 °. The function of the bevels 27 on the lower sides 21 'of the spacers is to push out the broken rock, which can accumulate in the bosom 11 between the base 50 of the section and the front lever 20, when folding the front levers 20. For the preferred interaction with the bevels 27 of the extrusion base section 50 contains both side of the middle block 51, in which, in particular, can be seen in figure 2, there are both front and rear holes for the pivot pins 5 and 7, respectively, of the levers 20, 30, the corresponding intermediate beam 52, the upper st an oron 53 which at an angle of inclination here essentially 45 ° obliquely descends from the middle block 51 in the direction of the side flaps 54 installed at intervals from the middle block 51 and on both sides of it. The inclined surfaces 53 form inclined bottoms located exactly under the front levers and due to which it is possible to lead to pieces and other broken rock that inadvertently fall into the bosom between the front lever 20 and the base 50 of the section. So, the inclined bottoms 53 provide abduction of the broken rock to the side. Under the middle block 51, intermediate beams 52 and side shields 54, a bottom sheet 61 is welded that extends over the entire width of the base of the section 50 and under which another power bottom sheet 78 is welded, having a longitudinal slot 79 here, the welds being located and made as a weld in a longitudinal slot 79. Under the bottom sheet, additional sheet layers can also be welded from below (sandwich type construction).

The overview of figures 1-3 shows that both side flaps 54, which are continuous at least between the hinge bath 9 and the rear end of the base, between the front connecting hinge 6 for the front arm 20 and the rear connecting hinge 30 for the rear arm 30 are extremely low circuit. Between both of these connecting hinges 6, 8, the upper edge 56 of the side flaps partially extends, respectively, at a level noticeably below the pivot axis 5 ′ of the front arm 5, and in the embodiment shown, even below the pivot axis 8 ′ of the rear arm 30. Upper edge 56 the side flaps 54 are located noticeably lower and closer to the lower side of the base 50 of the section than has been so far accepted in accordance with the prior art so that the broken rock can be diverted to the side. Due to the lowered upper edge 56, the entire broken rock can be freely taken to the side over the side flaps 54. At the same time, the broken rock or pieces of rock, which, as necessary, continue to be centered on the upper side of the middle block 51 of the base 50 when folding section 10 of the roof support can be forced upward through the vertical passages 26 for broken rock in the front arm 20 and thus also do not interfere with the folding (pushing) of the shield support section 10.

5-7 show a second embodiment of a section base 150. Identical parts are indicated by positions increased by 100. The base 150 also includes a hinge bath 109 for an expansion strut, behind which a middle block 151 is welded to a continuous power bottom plate 160. The middle block 151 is provided with a front one, i.e. closer to the hinge bath 109, an opening 161 for the front lever pivot pin and a lower hole 162 for the rear lever pivot pin, and both side flaps 154 are located on the sides of the middle block 151 with an interval from it. Both side flaps 154 are provided with safety means for (not shown) of the pivoting fingers, respectively pushed in from the outside, i.e. from the lower side surface 170 of the base of the section 150, and the stoppers 163 and 164 of the fingers on the side flaps 154 located inside the shield support section in the mounted state and adjacent to the walking beam, consist of locking plates or the like, whose width in the light is less the diameter of the holes 161, 162 for the fingers in the middle block 151, while the ring flaps 165 and 166 are welded to the side flap 154, which is mounted externally, respectively, into which, to prevent the pivot pin from being mounted, it is dropped out A safety device, such as a steel strip, can be inserted from the hinge hole and fixed there. As, in turn, is well shown in the top view in Fig. 5, between the middle block 151 and each side flap 154 there is a corresponding intermediate beam 152, the upper side of which has a bevel 153, converging in the form of a bath to the ends of the intermediate beam 152. The intermediate beams 152 also form inclined bottoms located under the front lever for leading to the side of broken or rock, which could be collected in the sinus between the hinge holes and the connected levers.

Unlike the previous embodiment, here both side flaps 154 do not have any lowered contour, and the upper edge 156 extends along the entire length of the section base 150 noticeably above the rear arm pivot axis 108 '. In the region of the position in which the inclined bottoms 153 of the intermediate beams 152 are located, the intermediate flaps 154 are provided with similar windows with grooves 175, the lower edge of which 176 is on a straight line with the inclined surface of the inclined bottoms 153, so that pieces of rock can be led away through the groove 175. Therefore, the grooves 175 in the side flaps 154, as in the previous embodiment, serve to support the lateral abduction of the broken rock.

On Fig and 9 shows another example implementation of the front lever 220 according to the utility model. The front arm 220 also contains two rectangular longitudinal cross-sections spaced apart from each other 221, ending respectively parallel to each other in the lower fork hinge 223 and the upper fork hinge 224 with finger holes, or hinge holes 223A and 224A. On the lower sides 221 ′, both longitudinal struts 221, as in the previous embodiment, are provided externally with bevels 227 as displacement bevels. However, unlike the previous embodiment, here, in the gap between both longitudinal struts 221, not one single middle bridge is fixed, but two middle bridge elements 222 and 282, of which the front middle bridge element 282 is installed closer to the fork hinge 223 from the base of the section than back element 222 of the middle jumper. The front side 285 of the front element 282 of the middle jumper, located closer to the fork hinge 223, is provided with a groove 287, and between the front side 285 and the fork hinge 223 there is a first vertical passage 286 for the broken rock 286, while between the rear side of the front element 282 of the middle the jumper and the front side 225 of the more distant rear element 222 of the middle jumper made the second vertical passage 226 for the broken rock. Both elements 222 and 282 of the middle bridge here consist of solid (i.e. not hollow) blocks or profiles and are welded by means of the circumferential welds 290 and 229, respectively, with longitudinal struts 221. While the rear element 222 of the middle bridge, located closer to the blocking fence extends essentially along the entire depth of the longitudinal struts 221, in FIG. 8 it is especially clearly seen that the front middle bridge element 282 extends essentially about half the depth of the longitudinal struts 221. On the lower side 288, the middle bridge element 282 is provided with two wedge surfaces 292, 293 that displace the broken rock either to one passage 286 or to the other passage 226 for the broken rock. At the same time, due to the interval between the wedge-shaped bottom side 288 of the middle bridge element 282 and the lower side 221 'of the longitudinal struts 221, free space is created under the front middle bridge element 282, in which small amounts of broken rock can accumulate, which do not prevent folding or lowering of the front levers 220 Due to the additional connecting element (element 282 of the middle bridge) between both longitudinal struts 221, the bending strength of the front arm 220 is significantly increases compared with the embodiment in which a continuous vertical passage is made for the broken rock.

For a specialist, from the previous description, many modifications follow that are included in the scope of protection of the considered claims of the utility model formula. The design of the middle block and the intermediate beams of the base of the section can be implemented using solid elements or using hollow profiles. The middle jumpers or elements of the middle jumpers of the levers may consist of continuous spacers, boxes, blocks or hollow profiles. To determine the contours and to create inclined bottoms, many design possibilities are opened. Depending on the stiffness of the intermediate beams and the general stiffness of the base of the section, they can be constructed from hollow box-shaped profiles or from solid elements and thereby realize sandwich-type structures. Within a wide range, the geometry of the grooves or the shape of the contour of the side flaps can also vary, and, in particular, depending on the basic construction of the section bases. The utility model within the protection of the considered claims of the utility model formula can also be used with other possibilities of securing the levers, for example, using insertable rotary fingers.

Claims (28)

1. The section of the shield mechanized lining for underground mining with two bases (50; 150) sections and four swinging levers (20; 30) to create a lever mechanism (2), of which two swinging levers (20) form the front swinging levers, which accordingly, with the help of the front pivot pin (5), the sections are rotatably mounted on the base (50; 150), and of which two swinging arms form the rear swinging arms, which are respectively mounted on the base (50; 150) of the section with the possibility of rotation by means of the rear pivot pin (8), and each swinging lever (20; 30) has two longitudinal struts (21, 31), which at their ends in the form of the lower as well as the upper fork joints (23, 24; 33, 34) protrude the middle jumper (22; 32), rigidly connecting the longitudinal struts, and each base (50; 150) of the section has a middle block (51; 151) with front and rear holes (161; 162) for pivoting fingers, and on the sides of the middle block (51; 151) side flaps (54; 154), characterized in that at least the middle jumpers (22; 282) of the front swing arms (20; 220) are spaced apart from the lower fork joints (23; by their front side (25; 285); 223) front swing levers (20; 220) with the formation of vertical passages (2 6; 28 6) for the broken rock and / or that the bases (50; 150) of the section are equipped with inclined bottoms (53; 153) to lead the broken rock to the side. 2. Section according to claim 1, characterized in that the middle jumpers (32) of the rear levers (30) with their front side (35) are separated from the lower fork hinges (33) of the rear levers (30) with the formation of vertical passages (36) for the broken breed. 3. Section according to claim 1, characterized in that the vertical passages (26; 36) for the broken rock pass at least 25%, preferably about 30-50% of the length of the swinging arms (20; 30) between their rotary axes. 4. Section according to claim 1, characterized in that the middle bridge contains several elements (282, 222) of the middle bridge, and between the element (282) of the middle bridge and the forked joint (223), a first vertical passage (28 6) is made for the broken rock and preferably between the elements (282; 222) of the middle bridge, at least one or the other vertical passage (22 6) for the broken rock. 5. Section according to claim 4, characterized in that the middle bridge element (282) located adjacent to the lower fork hinge (223) has a groove (287) or a recess on its front side (285). 6. Section according to claim 4, characterized in that the middle bridge element (282) located adjacent to the lower fork hinge (223) is wedge-shaped on its lower side (288). 7. Section according to one of claims 4, 5 or 6, characterized in that the middle bridge element (282) located adjacent to the lower fork hinge (223) extends essentially to only half the length of the longitudinal struts (221) . 8. Section according to claim 1, characterized in that the longitudinal struts (21; 221) of the front levers on their lower sides (21 ') are equipped with bevels (27; 227) of displacement. 9. Section according to claim 8, characterized in that the bevels (27; 227) of the displacement are bevels on the corresponding outer edge of the longitudinal struts (21). 10. Section according to claim 1, characterized in that the front sides (35) of the middle jumpers (32) on the lower side are beveled. 11. Section according to claim 9 or 10, characterized in that the bevels (27) on the lower sides of the longitudinal struts (21) pass at an angle of about 4 5 °. 12. The swinging arm of the section of the shield mechanized roof support according to claim 1 with two longitudinal struts (21, 31, 221), which with their ends in the form of the lower as well as the upper fork joints (23, 24; 33, 34) for installing the swinging lever ( 20; 30; 220) with the possibility of rotation, protrude behind the middle bridge (22; 32) rigidly connecting the longitudinal struts, characterized in that the middle bridge (22; 32; 282, 22) with its front side (25; 35; 285, 225) distance from the lower fork hinge (23; 33; 223) with the formation of a vertical passage (26; 36; 286, 226) for the broken rock. 13. The lever according to item 12, wherein the vertical passages (2 6; 3 6) for the broken rock pass at least 25%, preferably about 30-50% of the length of the swinging levers (20; 30) between their rotary axes . 14. The lever according to claim 12, characterized in that the middle bridge contains several elements (282, 222) of the middle bridge, and between the element (282) of the middle bridge and the forked joint (223), a first vertical passage (286) is made for the broken rock, and preferably between the elements (282; 222) of the middle bridge at least one or the other vertical passage (226) for the broken rock. 15. The lever according to 14, characterized in that the element (282) of the middle bridge, located adjacent to the lower fork hinge (223), has a groove (287) or a recess on its front side (285). 16. The lever according to 14, characterized in that the element (282) of the middle bridge, located next to the lower fork hinge (223), is wedge-shaped on its lower side (288). 17. The lever according to one of paragraphs.14, 15 or 16, characterized in that the element (282) of the middle bridge, located next to the lower fork hinge (223), extends essentially only to half the depth of the longitudinal struts (221) . 18. The lever according to claim 12, characterized in that the longitudinal struts (21; 221) of the front levers on their lower sides (21 ') are equipped with bevels (27; 227) of displacement. 19. The lever according to p. 18, characterized in that the bevels (27; 227) of the displacement are bevels on the corresponding outer edge of the longitudinal struts (21). 20. The lever according to item 12, characterized in that the front sides (35) of the middle jumpers (32) on the lower side are beveled. 21. The lever according to claim 19 or 20, characterized in that the bevels (27) on the lower sides of the longitudinal struts (21) pass at an angle of about 45 °. 22. The base of the section for the section of the shield mechanized roof support according to claim 1 with the middle block (51; 151), on which there is a front hole (161) for the finger to install the front lever and a rear hole (162) for the finger to install the rear lever, and on both sides of which there are side shields (54; 154), characterized in that between at least one of the side shields (54; 154) and the middle block (51; 151) there is an inclined bottom (53; 153) for deflecting the broken rock to the side. 23. The base of the section according to claim 22, wherein the inclined bottoms (53; 153) extend respectively between the middle block (51; 151) and the side shields (54; 154) and descend in the direction from the middle block (51; 151) to the side shields (54; 154). 24. The base of the section according to claim 22, characterized in that the side flaps (154) are provided with recesses or grooves (175), the inclined bottoms (153) ending in the lower edge (176) of the groove (175) or above it. 25. The base of the section according to claim 22, characterized in that the side flaps (54) between the front and rear hinges (5; 8) for the pivot pin have a lowered contour with the top edge (56) of the side flap in the direction of which the inclined bottoms ( 53). 26. The base of the section according A.25, characterized in that the upper edge (56) of the side flap partially extends at the same level or below the pivot axis (8 ') of the rear pivot pin and, accordingly, the rear lever. 27. The base of the section according to claim 22, characterized in that the bases (50; 150) of the section have intermediate beams (52; 152) between the middle block (51; 151) and the side shields (54 '; 154), the upper sides (53 ; 153) which are beveled and form inclined bottoms. 28. The base of the section according to claim 22, characterized in that installation means (165, 166) are formed in the side flaps (154) for the finger stops.