CN218778616U - Novel I-steel adsorbs hoist and mount by force device - Google Patents

Abstract

The utility model relates to a hoisting device, which provides a novel I-steel strong adsorption hoisting device, comprising I-steel, wherein elastic guide mechanisms are symmetrically arranged on a transverse rod, and one side opposite to the elastic guide mechanisms is abutted against the surface of the I-steel; the symmetrical swing mechanisms are hinged at two ends of the transverse rod, and pull ropes are arranged at the movable ends of the symmetrical swing mechanisms; the connecting rod mechanism is arranged at the bottom of the movable end of the symmetrical swinging mechanism, and the bottom end of the connecting rod mechanism is connected with the elastic guide mechanism; the bottom end of the elastic abutting mechanism abuts against the upper surface of the I-shaped steel and applies pressure to the I-shaped steel to avoid shaking during hoisting; this hoist device can realize the automatic centre gripping to the I-steel position when hoist, and the in-process of hoist and mount after the centre gripping, the stability of I-steel is higher, is difficult to take place to become flexible to after hoist to the assigned position, automatic loosen the I-steel during the whereabouts, need not artifical manual to carry out the centre gripping to the I-steel, improved the efficiency of hoist and mount to a very big degree.

Description

Novel I-steel adsorbs hoist and mount by force device

Technical Field

The utility model relates to a lifting device especially relates to a novel I-steel adsorbs hoist device by force.

Background

When the I-steel is hoisted in the construction process in the building industry, hoisting equipment needs to be used, in the use process of the existing hoisting equipment, the I-steel needs to be manually bound, or the I-steel is placed on a base and matched with a sleeve, the position of the I-steel is fixed under the action of a high-strength spring, and the position of the I-steel is adjusted in the height direction through a stretching piece.

However, during hoisting, binding before and after hoisting is inconvenient, the working strength is high, falling is easy to occur in the hoisting process, and the stability of the device is low.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the utility model is to provide a novel I-steel adsorbs hoist and mount by force device aims at solving the problem that proposes in the above-mentioned background art.

The embodiment of the utility model provides a realize like this, a novel I-steel adsorbs hoist device by force, including the I-steel and set up the transverse bar in the I-steel side, still include:

the elastic guide mechanisms are symmetrically arranged on the transverse rod, and one opposite side of each elastic guide mechanism is abutted against the surface of the I-shaped steel and used for fixing the position of the I-shaped steel so as to prevent the I-shaped steel from sliding;

the symmetrical swing mechanisms are hinged to two ends of the transverse rod, pull ropes are mounted at the movable ends of the symmetrical swing mechanisms, and the pull ropes are connected with external traction equipment and used for adjusting the height of the I-shaped steel;

the connecting rod mechanism is arranged at the bottom of the movable end of the symmetrical swinging mechanism, and the bottom end of the connecting rod mechanism is connected with the elastic guide mechanism;

the elastic abutting mechanism is oppositely arranged on the inner side of the symmetrical swing mechanism, the bottom end of the elastic abutting mechanism is abutted to the upper surface of the I-shaped steel, and pressure is applied to the I-shaped steel to avoid shaking during hoisting.

Preferably, the elastic guide mechanism comprises a transverse sliding chute arranged on the transverse rod, a transverse sliding rod slidably mounted on the transverse sliding chute and a longitudinal rod mounted on the side surface of the transverse sliding rod;

the top end of the longitudinal rod is hinged with an upper roller, and the bottom end of the upper roller is hinged with a lower roller;

an elastic supporting piece I is further arranged in the transverse sliding groove, and one end of the elastic supporting piece I is connected with the transverse sliding rod.

Preferably, the symmetrical swing mechanism comprises a swing rod I hinged on the transverse rod and a transverse rod II arranged on one side surface of the swing rod;

the first swing rod is also provided with a guide groove, and the guide groove is connected with a fixed pile arranged on the second transverse rod in a sliding manner;

and a guide rod is further installed on the side surface of the transverse rod II.

Preferably, the link mechanism comprises a second longitudinal rod arranged at the bottom end of the second transverse rod and a movable rod hinged at the bottom end of the second longitudinal rod;

the movable rod is hinged with the movable end of the elastic guide mechanism so as to tightly support the I-shaped steel when the longitudinal rod II is lifted.

Preferably, the elastic abutting mechanism comprises a second oscillating bar hinged on the first oscillating bar and an abutting block arranged at the bottom end of the second oscillating bar;

the bottom of the abutting block abuts against the upper surface of the I-shaped steel;

and the adjacent abutting blocks are connected through the elastic supporting piece II.

An embodiment of the utility model provides a pair of novel I-steel adsorbs hoist device by force, this hoist device can realize the automatic centre gripping to the I-steel position when hoist, the in-process of hoist and mount after the centre gripping, the stability of I-steel is higher, is difficult to take place not hard up to after hoist and mount the assigned position, loosen the I-steel automatically during the whereabouts, need not artifical manual and carry out the centre gripping to the I-steel, improved the efficiency of hoist and mount in the very big degree.

Drawings

Fig. 1 is a schematic structural view of a novel i-steel strong adsorption hoisting device provided by an embodiment of the utility model;

fig. 2 is a front view of an elastic guide mechanism in the novel i-steel strong adsorption hoisting device provided by the embodiment of the utility model;

fig. 3 is a three-dimensional structure diagram of a second longitudinal rod in the novel i-steel strong-adsorption hoisting device provided by the embodiment of the utility model.

In the drawings: 1-i-steel; 2-a transverse bar; 3-a transverse chute; 4-a transverse slide bar; 5-longitudinal bar; 6, upper roller; 7-lower roller; 8, a first elastic support part; 9-oscillating bar I; 10-a guide groove; 11-a transverse rod II; 12-fixing the pile; 13-pulling a rope; 14-a guide bar; 15-longitudinal rod two; 16-a movable rod; 17-oscillating bar II; 18-a holding block; 19-elastic support member two.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The following detailed description is provided for the specific embodiments of the present invention.

As shown in fig. 1-3, a structure diagram of a novel i-steel strong-absorption hoisting device provided by an embodiment of the present invention includes an i-steel 1, a transverse rod 2, an elastic guide mechanism, a symmetrical swing mechanism, a link mechanism and an elastic abutting mechanism, wherein the elastic guide mechanism is symmetrically arranged on the transverse rod 2, and one side of the elastic guide mechanism opposite to the elastic guide mechanism abuts against the surface of the i-steel 1, so as to fix the position of the i-steel 1 and prevent the i-steel from sliding; the symmetrical swing mechanisms are hinged to two ends of the transverse rod 2, pull ropes 13 are mounted at the movable ends of the symmetrical swing mechanisms, and the pull ropes 13 are connected with external traction equipment and used for adjusting the height of the I-steel 1; the connecting rod mechanism is arranged at the bottom of the movable end of the symmetrical swinging mechanism, and the bottom end of the connecting rod mechanism is connected with the elastic guide mechanism; the elastic abutting mechanism is oppositely arranged on the inner side of the symmetrical swing mechanism, the bottom end of the elastic abutting mechanism is abutted to the upper surface of the I-shaped steel 1, and pressure is applied to the I-shaped steel 1 to avoid shaking during hoisting.

In the specific in-process of implementing at this embodiment, this hoist device can realize the automatic centre gripping to I-steel 1 position when hoist, and the in-process of hoist and mount after the centre gripping, I-steel 1's stability is higher, is difficult to take place not hard up to after hoist to the assigned position, automatic unclamp I-steel 1 during the whereabouts, need not artifical manual to carry out the centre gripping to I-steel 1, improved the efficiency of hoist and mount in the very big degree.

The utility model discloses an in the example, traction equipment can select for use the motor to drive hold-in range or chain to stretch in this embodiment, and the side of equipment is provided with vertical groove, vertical groove and the one end sliding connection of guide bar 14 to prevent that the in-process of hoist and mount from taking place to rotate.

As shown in fig. 1 and 2, as a preferred embodiment of the present invention, the elastic guide mechanism includes a transverse sliding slot 3 disposed on the transverse rod 2, a transverse sliding rod 4 slidably mounted on the transverse sliding slot 3, and a longitudinal rod 5 mounted on a side of the transverse sliding rod 4;

the top end of the longitudinal rod 5 is hinged with an upper roller 6, and the bottom end of the upper roller 6 is hinged with a lower roller 7;

an elastic supporting piece I8 is further arranged in the transverse sliding groove 3, and one end of the elastic supporting piece I8 is connected with the transverse sliding rod 4.

In the specific implementation process of the embodiment, when the transverse sliding rod 4 is stressed to slide along the transverse sliding groove 3 in use, the first elastic supporting piece 8 is stressed to generate elastic deformation, so that the upper roller 6 is hinged to a fillet at the top end of the I-shaped steel 1, and the lower roller 7 is abutted to the middle of the I-shaped steel 1 to prevent the I-shaped steel 1 from shaking; in addition, magnetic poles can be arranged on the inner sides of the upper roller 6 and the lower roller 7 according to requirements, so that the I-shaped steel 1 can be adsorbed conveniently.

As shown in fig. 1 and fig. 3, as another preferred embodiment of the present invention, the symmetric swing mechanism includes a first swing link 9 hinged on the first transverse rod 2, and a second transverse rod 11 disposed at a side of the first swing link 9;

the first oscillating bar 9 is also provided with a guide groove 10, and the guide groove 10 is in sliding connection with a fixed pile 12 arranged on the second transverse bar 11;

and a guide rod 14 is also arranged on the side surface of the transverse rod II 11.

In the specific implementation process of this embodiment, when the second transverse rod 11 receives a force in the height direction, the second transverse rod 11 translates in the vertical direction, and the fixing piles 12 arranged at the two ends of the second transverse rod 11 slide along the second transverse rod 11, so that the first oscillating bars 9 at the two sides oscillate in opposite directions along the two ends of the transverse rod 2.

As shown in fig. 1 and 3, as another preferred embodiment of the present invention, the link mechanism includes a second longitudinal rod 15 installed at the bottom end of the second transverse rod 11, and a movable rod 16 hinged at the bottom end of the second longitudinal rod 15;

the movable rod 16 is hinged with the movable end of the elastic guide mechanism so as to tightly support the I-shaped steel 1 when the second longitudinal rod 15 is lifted.

In the specific implementation process of the embodiment, when the second transverse rod 11 translates in the height direction, the second longitudinal rod 15 moves synchronously with the second transverse rod, so that the movable rod 16 at the bottom end of the second longitudinal rod 15 is pulled to swing, the transverse sliding rod 4 slides transversely along the transverse sliding groove 3, and the automatic locking of the i-shaped steel 1 is completed at the initial hoisting stage.

As shown in fig. 1, as another preferred embodiment of the present invention, the elastic abutting mechanism includes a second swing rod 17 hinged to the first swing rod 9, and an abutting block 18 disposed at the bottom end of the second swing rod 17;

the bottom of the abutting block 18 abuts against the upper surface of the I-shaped steel 1;

wherein, the adjacent abutting blocks 18 are connected by the second elastic supporting piece 19.

In this embodiment specific implementation's in-process, in this application the bottom of supporting tight piece 18 and 1 surperficial butt of I-steel, supporting tight piece 18 selects the great material of density to make, supporting tight piece 18 removes to select the graphic expression connected mode for use, still can decide from the middle part with it, and its one end is connected with pendulum rod 9 to it exerts the effort to I-steel 1 to promote to support tight piece 18.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (5)

1. The utility model provides a novel I-steel adsorbs hoist device by force, includes the I-steel and sets up the transverse bar in the I-steel side, its characterized in that still includes:

the elastic guide mechanisms are symmetrically arranged on the transverse rod, and one opposite side of each elastic guide mechanism is abutted against the surface of the I-shaped steel and used for fixing the position of the I-shaped steel so as to prevent the I-shaped steel from sliding;

the symmetrical swing mechanisms are hinged to two ends of the transverse rod, pull ropes are mounted at the movable ends of the symmetrical swing mechanisms, and the pull ropes are connected with external traction equipment and used for adjusting the height of the I-shaped steel;

the connecting rod mechanism is arranged at the bottom of the movable end of the symmetrical swinging mechanism, and the bottom end of the connecting rod mechanism is connected with the elastic guide mechanism;

the elastic abutting mechanism is oppositely arranged on the inner side of the symmetrical swing mechanism, the bottom end of the elastic abutting mechanism is abutted to the upper surface of the I-shaped steel, and pressure is applied to the I-shaped steel to avoid shaking during hoisting.

2. The novel I-steel strong adsorption hoisting device according to claim 1, wherein the elastic guide mechanism comprises a transverse sliding groove arranged on the transverse rod, a transverse sliding rod slidably mounted on the transverse sliding groove, and a longitudinal rod mounted on the side surface of the transverse sliding rod;

the top end of the longitudinal rod is hinged with an upper roller, and the bottom end of the upper roller is hinged with a lower roller;

an elastic supporting piece I is further arranged in the transverse sliding groove, and one end of the elastic supporting piece I is connected with the transverse sliding rod.

3. The novel I-steel strong adsorption hoisting device according to claim 1, wherein the symmetrical swing mechanism comprises a first swing rod hinged on the transverse rod and a second transverse rod arranged on one side surface of the swing rod;

the first oscillating bar is also provided with a guide groove, and the guide groove is in sliding connection with a fixed pile arranged on the second transverse bar;

and a guide rod is further installed on the side surface of the transverse rod II.

4. The novel I-steel strong adsorption hoisting device according to claim 3, wherein the link mechanism comprises a second longitudinal rod arranged at the bottom end of the second transverse rod and a movable rod hinged at the bottom end of the second longitudinal rod;

the movable rod is hinged with the movable end of the elastic guide mechanism so as to tightly support the I-shaped steel when the longitudinal rod II is lifted.

5. The novel I-steel strong-adsorption hoisting device according to claim 3, wherein the elastic abutting mechanism comprises a second swing rod hinged on the first swing rod and an abutting block arranged at the bottom end of the second swing rod;

the bottom of the abutting block abuts against the upper surface of the I-shaped steel;

and the adjacent abutting blocks are connected through the second elastic supporting piece.

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