RU2056001C1 - Connecting member - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: connecting member has two similar half-members interconnected by means of teeth and locking member made in form of body of revolution provided with lock. Locking member is located in center perpendicularly to plane of connecting member between bow-shaped surfaces formed on inner wall of each half-member in such a position that lock is engageable with grooves made on bow-shaped surfaces. Locking member is rotatable about its axis. It is provided with at least one groove which forms (together with grooves on bow-shaped surfaces of half-members) part of toroidal or screw chamber where lock is located. Lock is made of wire in form of spring whose one end is secured on pin. Besides that, one end of pin is provided with head for limiting its axial displacement; outer surface of locking member and bow-shaped surfaces of half-members are taper in shape. EFFECT: enhanced reliability. 4 cl, 9 dwg

Description

 The invention relates to general mechanical engineering, in particular to the construction of connecting links of heavily loaded round link chains, and can be used in the mining industry in scraper conveyors, mechanisms for moving coal combines, plow installations to move them along the face when it is necessary to provide quick connection of chain links, for example , during repair, as well as in other sectors of the national economy, for example, shipbuilding.

Known connecting link traction round link chains containing two identical C-shaped half links. The fork and finger of each half link form a butt joint. Butt joints are rigidly bonded to each other with a locking finger [1]
This design of the connecting link is not equal to the main link of the chain.

It is also known a chain link containing two identical half links connected to each other by teeth and a locking element, for example, a finger (checks) with a stop, the check being placed in the center perpendicular to the plane of the link so that the stop interacts with grooves on the inner wall of each half link [2 ]
The connecting link of this design, even at ultimate torsional loads, is more durable than the main chain link.

 However, a significant drawback of this design is the closing element (check).

 The check is a steel finger with an annular groove filled with elastic synthetic material on which two annular grooves are made, in which two spring rings are installed. When the checks are hammered into the link due to the elastic properties of the synthetic material and the springing of the steel rings, it is possible to assemble the installation of the spring rings in the corresponding grooves on the arc surfaces of the half links.

 However, taking into account operating conditions (scraper conveyors for coal transportation, plow installations for coal mining, etc.), axial blows to the check with pieces of coal or rock are possible, as a result of which the checks are pressed out and, as a result, the chain is opened.

 In addition, during long-term storage of the link, the elastic properties of the synthetic material and, as a result, the reliability of the entire connecting link are lost.

 Given the limited space under operating conditions (mine lavas with a low coal seam capacity of up to 600 mm), the non-rigidity of the structure, the traction or idle chain branch is weighted, it is quite difficult to correctly install the checks by hammering. There are cases when the checks are installed on only one snap ring. In this case, the check with one end will protrude beyond the size of the connecting link, and when passing through the conveyor drive star, it will be pressed out and the circuit will open.

 The aim of the invention is to increase the reliability of the connecting link and simplifying the design of the locking element. This is achieved by the fact that in the known connecting link containing two identical half links with internal arc surfaces, grooves and teeth connecting the half links, is installed in the center between the arc surfaces of the half links perpendicular to their plane and made in the form of a body of revolution, a locking element with a stopper installed with the possibility of interaction with the grooves and with the means of its rotation on one of the ends. The locking element is made in the form of a finger with at least one groove forming, with grooves on the arc surfaces of the half-links, the parts of the toroidal or helical cavity in which the stopper is placed.

 The stopper can be made of wire in the form of a spring, one end of which is mounted on a finger.

 A head is made at one of the ends of the finger to limit its axial movement.

 The outer surface of the locking element and the arc surfaces of the half links can be made conical.

 The main difference from the prototype is that the locking element in the form of a finger is made rotatable around its axis, which provides a mechanical hard circuit from axial movement. In this design there is no elastic and elastic elements that are the basis in the prototype.

 The closure of the connecting link always occurs without significant mechanical effort, and provides the ability to control the reliability of the connection, which is impossible in the design of the prototype.

 In the prototype, the locking element (pin) is hammered, while the possibility of damage to the elastic synthetic material is not excluded and there is no possibility of control.

 Locking on helical lines with these advantages further increases the reliability of the connection.

 In the case of using a finger with an annular groove as a locking element, the design and manufacturing technology of the locking element are greatly simplified and there is no need for an additional element (lock from rotation).

 The implementation of the conical finger allows you to further increase the reliability of the connecting link as a whole due to the fact that in this case, technological gaps are selected during assembly.

 The invention is illustrated by drawings, where in Fig.1 shows a connecting link, General view; figure 2 section aa in figure 1; figure 3 locking element in the form of a finger with an annular groove and a wire stopper; figure 4 section aa in figure 3; in Fig.5 locking element in the form of a finger with a helical groove and a stopper in the form of a spiral wire spring; FIG. 6 is a view along arrow B in FIG. 5; in FIG. 7 locking element in the form of a conical finger with an annular groove and a wire stopper; on Fig section AA in Fig.7; Fig.9 locking element in the form of a conical finger and with a wire stopper in the form of a spring.

 The connecting link consists of two identical half links 1 and 2, interconnected by teeth 3, 4 and 5 of half link 1 and teeth 6, 7 and 8 of half link 2.

 The locking element is made in the form of a finger 10 (Fig. 3), on which an annular groove 16 is made, in which a wire 11 is placed, fixed at one end in a fixing socket 18. A head 12 is made at one end of the finger to limit axial movement of the finger during installation and a groove 15 as a means of turning it around its axis.

 The locking element is placed in the connecting link between the arc surfaces 13 of the half-link 1 and 14 of the half-link 2. On each arc surface 13 and 14, at least one annular groove 20 is made in which the wire 11 is placed. The head of the finger 12 is included in the sharpening elements during installation 9, made concentric to the arc surfaces at the end of the half-links 1 and 2.

 The locking element can be made in the form of a finger with a helical groove 21 (FIGS. 5 and 6), in which the wire 22 is placed in the form of a spiral spring, one end of which is installed in the locking socket 23, and the other end with the bend 25 in the working position is bent ( see the dash) along the groove 24. The bend in this embodiment serves as a lock from turning the finger during operation.

 The finger 10 can be made conical with an annular groove (Fig.7 and 8) or with a helical groove (Fig.9). In this case, the arc surfaces on the half links are made with the corresponding cone and with an annular or helical groove.

 The connecting link operates as follows.

 In the mating links of the main chain, half links 1 and 2 are installed, which are connected by teeth 3 8. Between the arc surfaces 13 and 14, finger 10 is installed perpendicular to the plane of the link from the side of the sharpening elements 9 until the head 12 enters the corresponding sharpening 9 on half links. In this case, the annular groove 16 of the finger 10 will be opposite the grooves 20 on the arc surfaces 13 and 14. In the fixing socket 18, the wire 11 is inserted with the bent end 19, and a key for rotation (not shown) in the groove 15. When the finger is turned clockwise, the wire 11 is drawn into the toroidal cavity formed by the ring groove 16 of the finger and the grooves 20 on the arc surfaces 13 and 14 of the half links 1 and 2. The finger is rotated one full revolution. In this case, the wire 11 performs the function of a stopper from the axial movement of the finger.

 When disassembling, the free end of the wire 11 is bent out of the groove 16 and, by reverse rotation of the finger 10, the wire is pressed out of the toroidal cavity, the wire is removed from the fixing socket 18, the finger 10 is removed and the half-links are opened.

 In a similar way, the assembly and disassembly of the locking element shown in Fig.7. In this case, the conical surfaces of the finger and the arc surfaces on the half links serve as a limiter of axial displacement when installing the finger.

 The assembly of the connecting link with the locking element shown in FIG. 5 (pin with a helical groove) and FIG. 9 (conical pin with a screw groove) differs from the previously stated in that the wire is wound onto the finger before link assembly. For this, the bent end of the wire 26 inserted into the fixing socket 23 of the finger, the wire is wound on the finger in the screw groove 21.

 Similarly, the assembly of the main chain and the half link of the connecting link is carried out. Connect half-links 1 and 2 by means of teeth 3 8. Into the space between the arc surfaces 13 and 14, perpendicular to the plane of the link, screw along the helix of the groove made on the arc surfaces of the half links, a finger with a wound wire by means of a key inserted into the groove 24, made at the end of the finger. When the ends of the finger are in the same plane with the plane of the link, the free end of the spring 25 is bent along the groove 24, as shown by dashed lines in Fig. 5, into the space between the half links 1 and 2. In this position, the free end acts as a latch for turning the locking element.

 The disassembling of the locking devices shown in FIGS. 5 and 9 is performed in the reverse assembly sequence.

Claims (4)

 1. CONNECTING LINK, containing two identical half links with internal arc surfaces with grooves and teeth connecting the half links, mounted in the center between the arc surfaces of the half links perpendicular to their plane and made in the form of a body of revolution, a locking element with a stopper installed with the possibility of interaction with the grooves, and with the means of its rotation on one of the ends, characterized in that the locking element is made in the form of a finger with at least one groove forming with grooves on the arcs x the surfaces of the half-links of the part of the toroidal or helical cavity in which the stopper is placed.  2. The link according to claim 1, characterized in that the stopper is made of wire in the form of a spring, one end of which is mounted on a finger.  3. The link according to claim 1, characterized in that a head is made on one of the ends of the finger to limit its axial movement.  4. The link according to claim 1, characterized in that the outer surface of the locking element and the arc surfaces of the half links are made conical.

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