CN215209243U - Vertical bidirectional tamping mechanism - Google Patents

Abstract

The utility model provides a perpendicular two-way tamping mechanism, includes mounting panel, support, drive assembly, switching-over subassembly, tamping hammer, its characterized in that, the support is fixed to be located on the mounting panel, drive assembly and switching-over subassembly respectively with support rotatable coupling, still be equipped with the transmission crank between drive assembly and the switching-over subassembly, drive assembly and transmission crank drive are connected, the switching-over subassembly is connected with the transmission crank drive, tamping hammer is fixed to be located the centre of switching-over subassembly. This intermittent type formula switching-over tamping mechanism can change the operating condition of tamping hammer, realizes the circulation of intermittent type formula and tamps the material in two horizontal position, not only can increase tamping mechanism's work efficiency, can avoid the device to increase because repeated one direction tamps the wearing and tearing risk that increases simultaneously, increases tamping mechanism's life.

Description

Vertical bidirectional tamping mechanism

Technical Field

The utility model relates to a tamping equipment technical field specifically is a perpendicular two-way tamping mechanism.

Background

The tamping hammer of tamping machine is carrying out the tamping during operation, and the position of tamping hammer is for reciprocating, and the motion of each time all can carry out the tamping to the material, but current tamping unit mostly can only carry out one-way hammer pressure tamping material, and such tamping unit work efficiency is lower, leads to the tamping time extension and makes the device life-span shorten relatively, and the repeated one direction tamping of device has also increased the risk of device wearing and tearing simultaneously.

For example, chinese patent document discloses a guiding device for a tamping hammer of a coke oven tamping machine [ application No.: CN201320477705.3], including: wear-resisting guide block, frame and tamping hammer pole, its characterized in that installs wear-resisting guide block additional around the tamping hammer pole is through sliding friction and prevent that the tamping hammer from doing the horizontal hunting, and wear-resisting guide block is fixed in the frame, and wear-resisting guide block is including welding steel construction and friction plate, and the welding steel construction is fixed in the frame, and the friction plate bonds on the face of welding steel construction towards the tamping hammer pole. The utility model adopts the structure that the wear-resistant guide block is additionally arranged in the radial direction of the hammer rod of the tamping hammer, thereby effectively limiting the transverse swing of the hammer rod of the tamping hammer and reducing the bending phenomenon of the tamping hammer caused by the swing of the hammer rod, thereby reducing the unplanned shutdown probability of the tamping machine and ensuring the normal operation of the equipment; because the friction surface adopts the friction plate, the collision noise of the hammer rod of the tamping hammer and the guiding device in the tamping operation process is reduced. According to the tamping hammer guide device of the coke oven tamping machine, although the guide problem of the tamping hammer is solved, the tamping hammer only presses materials in one direction, the working efficiency cannot be improved, and the abrasion risk increased by tamping in one direction is not solved.

To the above shortcoming, a two-way tamping mechanism is needed, which can change the hammering direction of a tamping hammer in the tamping mechanism, can realize hammering materials in two directions, not only can increase the working efficiency of the tamping mechanism, but also can avoid the abrasion risk of the device due to tamping in one repeated direction, and increase the service life of the tamping mechanism.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, provide perpendicular two-way tamping mechanism, can effectively solve the problem in the background art. The utility model discloses a realize through following technical scheme:

the utility model provides a perpendicular two-way tamping mechanism, includes right angle sliding plate, supplementary rotor plate, driving plate, tamping hammer and drive assembly, its characterized in that, supplementary rotor plate is located between right angle sliding plate and the driving plate, tamping hammer inlay card is in the middle of supplementary rotor plate, tamping hammer and supplementary rotor plate sliding connection, the sliding block respectively is equipped with to both sides around the tamping hammer, tamping hammer pass through the sliding block respectively with right angle sliding plate and driving plate sliding connection, still be equipped with drive crank between drive assembly and the driving plate.

Preferably, the driving assembly comprises a driving motor and a rotating shaft, and the driving motor is in driving connection with the rotating shaft.

Preferably, one end of the transmission crank is rotatably connected with the rotating shaft, and the other end of the transmission crank is fixedly connected with the transmission plate.

Preferably, the right-angle sliding plate comprises a horizontal sliding plate and a vertical sliding plate, and the included angle between the horizontal sliding plate and the vertical sliding plate is a right angle.

Preferably, a right-angle guide sliding groove is formed in the middle of the right-angle sliding plate, a limiting sliding groove is formed in the middle of the auxiliary rotating plate, and an auxiliary steering sliding groove is formed in the middle of the transmission plate.

Preferably, the tamping hammer is arranged in the limit sliding groove, the width of the middle part of the tamping hammer is the same as the size of the limit sliding groove, and the width of the two side parts of the tamping hammer is larger than the limit sliding groove; the sliding blocks on the front side and the rear side of the tamping hammer are respectively arranged in the right-angle guide sliding groove and the auxiliary steering sliding groove in a sliding mode, and the size of one end, away from the tamping hammer, of the sliding blocks on the front side and the rear side of the tamping hammer is respectively larger than the width size of the right-angle guide sliding groove and the auxiliary steering sliding groove.

The utility model has the advantages that:

the utility model discloses a perpendicular two-way tamping mechanism can be intermittent type formula the circulation tamp two ascending materials of vertical direction, has increased the work efficiency of tamping mechanism, has also avoided installing a repeated direction to tamp and the wearing and tearing risk that increases. The drive assembly drives the transmission plate to rotate through the transmission crank, under the assistance of the auxiliary steering sliding groove and the front end sliding block, the tamping hammer starts to steer and drives the auxiliary rotating plate to rotate, the relative position of the limiting sliding groove when the tamping hammer can be limited to rotate does not generate additional offset, the right-angle guide sliding groove can assist the tamping hammer to guide and offset to the vertical direction, the tamping hammer slides in the right-angle guide sliding groove on the right-angle sliding plate through the sliding block at the rear end, so that the longitudinal tamping state is changed into the transverse tamping state, the drive assembly continues to work, the tamping hammer changes the transverse tamping state back into the longitudinal tamping state until the working state of intermittent type circulation turning tamping is formed.

Drawings

Fig. 1 is a schematic view of the front side of the vertical two-way tamping mechanism of the present invention;

fig. 2 is a schematic plan view of the vertical two-way tamping mechanism of the present invention;

FIG. 3 is a schematic view of the reverse side of the vertical two-way tamping mechanism of the present invention;

fig. 4 is a schematic perspective view of the connection mode between the tamping hammer and the auxiliary rotating plate according to the present invention.

In the figure, a right-angle sliding plate 1, a horizontal sliding plate 11, a vertical sliding plate 12, a right-angle guide sliding groove 13, an auxiliary rotating plate 2, a limit sliding groove 21, a transmission plate 3, an auxiliary steering sliding groove 31, a tamping hammer 4, a sliding block 41, a driving assembly 5, a driving motor 51, a rotating shaft 52 and a transmission crank 6.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, a vertical two-way tamping mechanism includes a right-angle sliding plate 1, an auxiliary rotating plate 2, a transmission plate 3, a tamping hammer 4 and a driving assembly 5, wherein the auxiliary rotating plate 2 is disposed between the right-angle sliding plate 1 and the transmission plate 3, the tamping hammer 4 is embedded in the middle of the auxiliary rotating plate 2, the tamping hammer 4 is slidably connected with the auxiliary rotating plate 2, sliding blocks 41 are respectively fixedly disposed on the front side and the rear side of the tamping hammer 4, the tamping hammer 4 is slidably connected with the right-angle sliding plate 1 and the transmission plate 3 through the sliding blocks 41, and a driving crank 6 is further disposed between the driving assembly 5 and the transmission plate 3. Drive assembly 5 can drive driving plate 3 through drive crank 6 and rotate, under the transmission effect of driving plate 3 and the supplementary down of sliding block 41, tamping hammer 4 can shift in the slip and turn to, supplementary rotor plate 2 plays limiting displacement to tamping hammer 4.

Further, the driving assembly 5 includes a driving motor 51 and a rotating shaft 52, and the driving motor 51 is in driving connection with the rotating shaft 52.

Furthermore, one end of the transmission crank 6 is rotatably connected with the rotating shaft 52, and the other end of the transmission crank 6 is fixedly connected with the transmission plate 3. The drive crank 6, when subjected to the effect of rotation of the rotary shaft 52, can transfer the effect of rotation synchronously to the drive plate 3.

Further, the right-angle sliding plate 1 comprises a horizontal sliding plate 11 and a vertical sliding plate 12, and an included angle between the horizontal sliding plate 11 and the vertical sliding plate 12 is a right angle.

Further, a right-angle guide sliding groove 13 is formed in the middle of the right-angle sliding plate 1, a limiting sliding groove 21 is formed in the middle of the auxiliary rotating plate 2, and an auxiliary steering sliding groove 31 is formed in the middle of the transmission plate 3. The right angle direction sliding tray 13 can assist tamping hammer 4 direction offset to vertical direction, and the relative position when spacing sliding tray 21 can restrict tamping hammer 4 and rotate does not take place extra skew, and supplementary direction sliding tray 31 can assist tamping hammer 4 in step to take place ascending change in direction.

Further, the tamping hammer 4 is arranged in the limiting sliding groove 21, the width of the middle part of the tamping hammer 4 is the same as the size of the limiting sliding groove 21, and the width of the two side parts of the tamping hammer 4 is larger than the limiting sliding groove 21; the sliding blocks 41 on the front side and the rear side of the tamping hammer 4 are respectively arranged in the right-angle guide sliding groove 13 and the auxiliary steering sliding groove 31 in a sliding mode, and the size of one end, far away from the tamping hammer 4, of the sliding blocks 41 on the front side and the rear side of the tamping hammer 4 is respectively larger than the width size of the right-angle guide sliding groove 13 and the auxiliary steering sliding groove 31.

The utility model discloses a vertical two-way tamping mechanism, when the mechanism begins to work, tamping hammer 4 is vertical state, driving motor 51 starts, drive axis of rotation 52 rotates, axis of rotation 52 drives transmission crank 6 relatively to rotate in step, because transmission crank 6 and driving plate 3 are fixedly connected, so the driving plate 3 receives the motion effect of transmission crank 6 and also relatively rotates the skew, because sliding block 41 at the front end of tamping hammer 4 slides and locates in the auxiliary steering sliding groove 31 in the middle of driving plate 3, so will drive tamping hammer 4 anticlockwise to rotate and upwards deflect in the process of driving plate 3 rotating the skew, because tamping hammer 4 imbeds in the middle of auxiliary rotating plate 2, under the limiting action of limiting sliding groove 21, tamping hammer 4 and auxiliary rotating plate 2 will rotate and deflect along a certain angle in step, at this moment, sliding block 41 at the rear end of tamping hammer 4 slides in the right angle guide sliding groove on the right angle sliding plate, with the aid of the vertical guide of the right-angle guide sliding groove 13, the tamping hammer 4 can be moved in a rotational offset from the vertical sliding plate 12 to the transverse sliding plate 11 and can continue to press the material towards the transverse direction, with the continued operation of the drive assembly 5, the drive plate 3 is subjected to a reverse rotational offset by the drive effect of the drive crank 6, the tamping hammer 4 is retracted in the transverse direction, at which time the sliding block 41 at the rear end of the tamping hammer 4 slides in the right-angle guide sliding groove on the right-angle sliding plate, and with the aid of the vertical guide sliding groove 13, the tamping hammer 4 can be moved in a rotational offset from the transverse sliding plate 11 to the vertical sliding plate 12 and can continue to press the material towards the vertical direction, with the continued operation of the drive assembly 5, the tamping hammer 4 will form an intermittent, circulating tamping operation in both vertical directions.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Although terms such as the right-angle sliding plate 1, the lateral sliding plate 11, the vertical sliding plate 12, the right-angle guide sliding groove 13, the auxiliary rotating plate 2, the limit sliding groove 21, the driving plate 3, the auxiliary steering sliding groove 31, the tamping hammer 4, the sliding block 41, the driving assembly 5, the driving motor 51, the rotating shaft 52, the driving crank 6, etc., are used more frequently herein, the possibility of using other terms is not excluded. These terms are used merely to more conveniently describe and explain the nature of the present invention and should not be interpreted as imposing any additional limitations that are contrary to the spirit of the present invention.

Claims (6)

1. The utility model provides a perpendicular two-way tamping mechanism, includes right angle sliding plate (1), supplementary rotor plate (2), driving plate (3), tamping hammer (4) and drive assembly (5), its characterized in that, between right angle sliding plate (1) and driving plate (3) is located in supplementary rotor plate (2), tamping hammer (4) inlay card is in the middle of supplementary rotor plate (2), tamping hammer (4) and supplementary rotor plate (2) sliding connection, both sides respectively are fixed sliding block (41) that are equipped with around tamping hammer (4), tamping hammer (4) pass through sliding block (41) respectively with right angle sliding plate (1) and driving plate (3) sliding connection, still be equipped with between drive assembly (5) and driving plate (3) transmission crank (6).

2. A vertical two-way tamping mechanism according to claim 1, wherein said drive assembly (5) comprises a drive motor (51) and a rotatable shaft (52), said drive motor (51) and rotatable shaft (52) being drivingly connected.

3. A vertical, bi-directional tamping mechanism according to claim 2, wherein said drive crank (6) is rotatably connected at one end to said rotating shaft (52) and at the other end to said drive plate (3) said drive crank (6) is fixedly connected.

4. A vertical two-way tamping mechanism according to claim 1, wherein said right-angle sliding plates (1) comprise a transverse sliding plate (11) and a vertical sliding plate (12), the angle between said transverse sliding plate (11) and vertical sliding plate (12) being a right angle.

5. A vertical two-way tamping mechanism according to claim 1, wherein said right-angle sliding plate (1) is provided with a right-angle guiding sliding groove (13) in the middle, said auxiliary rotating plate (2) is provided with a limiting sliding groove (21) in the middle, and said driving plate (3) is provided with an auxiliary steering sliding groove (31) in the middle.

6. A vertical two-way tamping mechanism according to claim 5, wherein said tamping hammer (4) is disposed in a limiting slide groove (21), the width of the middle portion of said tamping hammer (4) is the same as the size of the limiting slide groove (21), and the width of the two side portions of said tamping hammer (4) is larger than the limiting slide groove (21); the stamping hammer is characterized in that sliding blocks (41) on the front side and the rear side of the stamping hammer (4) are respectively arranged in the right-angle guide sliding groove (13) and the auxiliary steering sliding groove (31) in a sliding mode, and the size of one end, far away from the stamping hammer (4), of the sliding blocks (41) on the front side and the rear side of the stamping hammer (4) is respectively larger than the width size of the right-angle guide sliding groove (13) and the auxiliary steering sliding groove (31).

Images