CN219118799U - Concrete vibrating rod auxiliary vibration device for constructional engineering - Google Patents

Abstract

A concrete vibrating rod auxiliary vibrating device for constructional engineering relates to a high-frequency built-in vibrating rod, and aims to solve the problem that the control accuracy of the existing vibrating rod on the vibrating depth is poor. The novel bracket is of a rectangular frame body structure, and the supporting legs are supported at the bottom of the bracket; the first platform is arranged on the first sliding rail; the gear is arranged on the side wall of the first platform, and the gear and the rack form a meshing structure; the first platform is driven to slide along the first sliding rail by the rotating gear; the second sliding rail is arranged on the first platform and is perpendicular to the first sliding rail; the second platform is arranged on the second sliding rail; the screw rod is connected between the second platform and the rotating disc; the second platform is driven to slide along the second sliding rail by rotating the rotating disc; the third sliding rail is vertically fixed on the second platform, and the third platform is arranged on the third sliding rail; the third platform is used for fixing the concrete vibrating rod; the third sliding rail is provided with scale values. The beneficial effects are that the accurate control to the vibration depth has been reached.

Description

Concrete vibrating rod auxiliary vibration device for constructional engineering

Technical Field

The utility model relates to a high-frequency built-in vibrating rod.

Background

The vibrating rod is a mechanical tool used in construction engineering construction, can enable concrete to be closely combined, eliminates honeycomb pitting phenomenon of the concrete, and improves the strength of the solidified concrete; when the concrete mixed by the concrete mixer is used for pouring a component, bubbles in the concrete must be removed, and a vibrating rod is used for tamping, so that the concrete can be tightly combined, and the purposes of improving the strength and ensuring the quality of the concrete component are achieved; at present, the conventional concrete vibrating rod is inconvenient, time-consuming and labor-consuming when a user changes the operation position in the using process due to the large motor volume and heavy weight, and influences the working efficiency, so that the portable high-frequency built-in vibrating rod is applied, and particularly see Chinese patent CN 206360373U, wherein the high-frequency built-in vibrating rod is connected with a rod head through one end of a rubber tube, a cavity coaxial with the rod head is arranged in the rod head, a vibrating device is arranged in the cavity, and a sealing connecting piece is arranged at the other end of the rubber tube; the high-frequency built-in vibrating rod is hand-held, and has the advantages of light weight and convenience in hand-held conversion; however, the construction machine needs to be held by both hands by a constructor for operation, and the position is manually switched, and meanwhile, the control precision of the constructor on the vibration depth is poor, so that the constructor is required to operate according to working experience.

Disclosure of Invention

The utility model aims to solve the problem that the control accuracy of the existing vibrating rod on the vibrating depth is poor, and provides an auxiliary vibrating device for a concrete vibrating rod for constructional engineering.

The utility model relates to an auxiliary vibration device of a concrete vibrating rod for constructional engineering, which comprises a bracket, N supporting legs, a first sliding rail, a rack, a first platform, a gear, a second sliding rail, a second platform, a screw rod, a rotating disc, a third sliding rail and a third platform, wherein the bracket is arranged on the bracket;

the support is of a rectangular frame structure, N supporting legs are supported at the bottom of the support, wherein N is an integer greater than 3;

the first sliding rail is horizontally paved on the bracket along the length direction of the rectangular frame body structure;

the first platform is arranged on the first sliding rail; the rack is horizontally arranged on the rectangular frame body structure and is parallel to the first sliding rail; the gear is arranged on the side wall of the first platform in a shaft connection mode, and meanwhile, the gear and the rack form a meshing structure; the first platform is driven to slide along the laying direction of the first sliding rail by the rotating gear;

the second sliding rail is horizontally arranged on the first platform, and the laying direction of the second sliding rail is perpendicular to the laying direction of the first sliding rail;

the second platform is arranged on the second sliding rail; one end of the screw rod is connected to the second platform through a shaft, the rotary disc is fixed at the other end of the screw rod, and the middle part of the screw rod is arranged at the edge of the first platform in a threaded connection mode; the second platform is driven to slide along the laying direction of the second sliding rail by rotating the rotating disc;

the third sliding rail is vertically fixed on the second platform, and the third platform is arranged on the third sliding rail in an up-and-down sliding manner; the third platform is used for fixing the concrete vibrating rod; meanwhile, a scale value is arranged on the third sliding rail and used for representing the vibration depth of the vibration rod.

Further, the auxiliary vibrating device further comprises a first limit bolt;

the first limit bolt is arranged on the first platform, and the bottom of the first limit bolt is contacted with the first sliding rail by rotating the first limit bolt.

Further, the auxiliary vibrating device further comprises a second limit bolt;

the second limit bolt is arranged on the second platform, and the bottom of the second limit bolt is contacted with the second sliding rail by rotating the second limit bolt.

Further, the auxiliary vibrating device further comprises a third limit bolt;

the third limit bolt is arranged on the third platform, and the bottom of the third limit bolt is in contact with the third sliding rail through rotating the third limit bolt.

Further, the auxiliary vibrating device further comprises a fixing clamp;

the fixing clamp is arranged at the groove of the third platform; the groove of the third platform is used for clamping the concrete vibrating rod and fixing the concrete vibrating rod through the fixing clamp.

Further, a first rotating handle is arranged on the end face of the rotating disc;

the position where the first rotary handle is arranged is not coincident with the circle center of the rotary disk.

Further, a second rotary handle is arranged on the end face of the gear;

the second rotary handle is arranged at a position which is not coincident with the circle center of the gear.

The using method of the auxiliary vibration device comprises the following steps: firstly, moving the auxiliary vibrating device to a position to be vibrated, vertically fixing a concrete vibrating rod on a third platform, and simultaneously ensuring that a vibrating head of the vibrating rod is contacted with a concrete surface, and recording a scale value of the third platform aligned to a third sliding rail as a first depth value; secondly, downwards adjusting the third platform according to the depth value to be vibrated, wherein the third platform is aligned with the scale value on the third sliding rail to be a second depth value, and the difference value between the first depth value and the second depth value is ensured to be equal to the depth value to be vibrated; after the third platform is adjusted, limiting and fixing the third platform through a third limiting bolt; and finally, turning on a switch of the concrete vibrating rod to start vibrating, at the moment, adjusting the front and rear positions of the concrete vibrating rod by rotating the rotating disc, and adjusting the left and right positions of the concrete vibrating rod by rotating the gear to accurately control the vibrating depth.

The beneficial effects of the utility model are as follows: the auxiliary vibration device utilizes the up-and-down adjustment of the third platform to achieve the accurate control of the vibration depth; meanwhile, the front and back sliding of the second platform and the left and right sliding of the first platform are utilized, so that the problem of manual position conversion of a constructor is solved; through the structure, constructors are free from being in direct contact with the vibrating rod, construction strength is reduced, manpower is saved, and vibration effect is improved.

Drawings

Fig. 1 is a schematic view of an overall structure of an auxiliary vibration device for a concrete vibration rod for construction engineering according to an embodiment;

FIG. 2 is a front view of a bracket in accordance with one embodiment;

FIG. 3 is a side view of a bracket in accordance with one embodiment;

FIG. 4 is a schematic diagram showing a positional relationship between a screw and a rotating disc and a first rotating handle according to a first embodiment;

fig. 5 is a top view of a third platform according to a first embodiment.

Detailed Description

The concrete vibration rod auxiliary vibration device for construction according to the present embodiment includes a bracket 1, N support legs 2, a first slide rail 3, a rack 4, a first platform 5, a gear 6, a second slide rail 7, a second platform 8, a screw rod 9, a rotary disk 10, a third slide rail 11, and a third platform 12, with reference to fig. 1 to 5;

the support 1 is of a rectangular frame structure, and N supporting legs 2 are supported at the bottom of the support 1, wherein N is an integer greater than 3;

the first sliding rail 3 is horizontally paved on the bracket 1 along the length direction of the rectangular frame body structure;

the first platform 5 is arranged on the first sliding rail 3; the rack 4 is horizontally arranged on the rectangular frame body structure, and the rack 4 is parallel to the first sliding rail 3; the gear 6 is arranged on the side wall of the first platform 5 in a shaft connection mode, and the gear 6 and the rack 4 form a meshing structure; the first platform 5 is driven to slide along the laying direction of the first sliding rail 3 by the rotating gear 6;

the second sliding rail 7 is horizontally arranged on the first platform 5, and the laying direction of the second sliding rail 7 is perpendicular to the laying direction of the first sliding rail 3;

the second platform 8 is arranged on the second sliding rail 7; one end of the screw rod 9 is connected to the second platform 8 in a shaft way, the rotary disk 10 is fixed at the other end of the screw rod 9, and the middle part of the screw rod 9 is arranged at the edge of the first platform 5 in a threaded connection way; the second platform 8 is driven to slide along the laying direction of the second sliding rail 7 by rotating the rotating disc 10;

the third sliding rail 11 is vertically fixed on the second platform 8, and the third platform 12 is arranged on the third sliding rail 11 in a manner of sliding up and down; the third platform 12 is used for fixing a concrete vibrating rod; meanwhile, the third sliding rail 11 is provided with a scale value which is used for representing the vibration depth of the vibration rod.

In the present embodiment, N is equal to 4,4 support legs 2 to ensure that the stand 1 is in a horizontal state; the bosses are respectively arranged on the front side and the rear side of the first platform 5, the bosses facilitate the fixation of the second slide rail 7, and the connection of the screw rod 9 is facilitated.

In the present embodiment, the direction in which the first platform 5 slides along the first slide rail 3 is horizontal left or horizontal right; the sliding direction of the second platform 8 along the second sliding rail 7 is horizontal forward or horizontal backward; the two are mutually perpendicular on the horizontal plane; when the auxiliary vibration device is used, the auxiliary vibration device is only required to be moved to a position to be vibrated, then the club head is vertically fixed on the third platform 12, meanwhile, the club head of the vibration bar is ensured to be in contact with the concrete surface, and at the moment, the scale value of the third platform 12 aligned with the third slide rail 11 is recorded as a first depth value; secondly, the third platform 12 is downwards adjusted according to the depth value to be vibrated, and at the moment, the third platform 12 is aligned with the scale value on the third sliding rail 11 to be a second depth value, wherein the difference value between the first depth value and the second depth value is ensured to be equal to the depth value to be vibrated; after the third platform 12 is adjusted, limiting and fixing the third platform 12 is realized through a third limiting bolt 15; finally, the switch of the concrete vibrating rod is turned on to start vibrating, at this time, the front and rear positions of the concrete vibrating rod are adjusted by rotating the rotary disk 10, and the left and right positions of the concrete vibrating rod are adjusted by rotating the gear 6, so that the accurate control of the vibrating depth is achieved.

In a preferred embodiment, the auxiliary vibrating device further comprises a first limit bolt 13;

the first limit bolt 13 is disposed on the first platform 5, and the bottom of the first limit bolt 13 is brought into contact with the first slide rail 3 by rotating the first limit bolt 13. The first limiting bolt 13 is used for limiting the sliding of the first platform 5, so that the first platform 5 is fastened on the first sliding rail 3.

In a preferred embodiment, the auxiliary vibrating device further comprises a second limit bolt 14;

the second limit bolt 14 is arranged on the second platform 8, and the bottom of the second limit bolt 14 is contacted with the second slide rail 7 by rotating the second limit bolt 14. The second limiting bolt 14 is used for limiting the sliding of the second platform 8, so that the second platform 8 is fastened on the second sliding rail 7.

In a preferred embodiment, the auxiliary vibrating device further comprises a third limit bolt 15;

the third limit bolt 15 is disposed on the third platform 12, and the bottom of the third limit bolt 15 is brought into contact with the third slide rail 11 by rotating the third limit bolt 15. The third limiting bolt 15 is used for limiting the third platform 12 to slide, so that the third platform 12 is fastened on the third sliding rail 11.

In a preferred embodiment, the auxiliary vibrating device further comprises a fixing clip 17;

the fixing clamp 17 is arranged at a groove of the third platform 12; the groove of the third platform 12 is used for clamping the concrete vibrating rod, and fixing the concrete vibrating rod through the fixing clamp 17.

In the present embodiment, the fixing clip 17 has a semicircular shape.

In a preferred embodiment, a first rotating handle 16 is provided on the end face of the rotating disk 10;

the first rotating handle 16 is arranged at a position which is not coincident with the center of the rotating disk 10. The first rotary handle 16 is provided to facilitate rotation of the rotary disk 10 and thus control the forward and backward sliding of the second platform 8.

In a preferred embodiment, a second rotating handle is arranged on the end face of the gear 6;

the second rotary handle is arranged at a position which is not coincident with the circle center of the gear 6. The second rotating handle is arranged to facilitate the rotation of the gear 6, thereby facilitating the control of the left-right sliding of the first platform 5.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (7)

1. The auxiliary vibration device for the concrete vibrating rod for the building engineering is characterized by comprising a bracket (1), N supporting legs (2), a first sliding rail (3), a rack (4), a first platform (5), a gear (6), a second sliding rail (7), a second platform (8), a screw rod (9), a rotating disc (10), a third sliding rail (11) and a third platform (12);

the support (1) is of a rectangular frame structure, and N supporting legs (2) are supported at the bottom of the support (1), wherein N is an integer greater than 3;

the first sliding rail (3) is horizontally paved on the bracket (1) along the length direction of the rectangular frame body structure;

the first platform (5) is arranged on the first sliding rail (3); the rack (4) is horizontally arranged on the rectangular frame body structure, and the rack (4) is parallel to the first sliding rail (3); the gear (6) is arranged on the side wall of the first platform (5) in a shaft connection mode, and the gear (6) and the rack (4) form a meshing structure; the first platform (5) is driven to slide along the laying direction of the first sliding rail (3) by the rotating gear (6);

the second sliding rail (7) is horizontally arranged on the first platform (5), and the laying direction of the second sliding rail (7) is perpendicular to the laying direction of the first sliding rail (3);

the second platform (8) is arranged on the second sliding rail (7); one end of the screw rod (9) is connected to the second platform (8) in a shaft way, the rotary disc (10) is fixed at the other end of the screw rod (9), and the middle part of the screw rod (9) is arranged at the edge of the first platform (5) in a threaded connection way; the second platform (8) is driven to slide along the laying direction of the second sliding rail (7) by rotating the rotating disc (10);

the third sliding rail (11) is vertically fixed on the second platform (8), and the third platform (12) is arranged on the third sliding rail (11) in a manner of sliding up and down; the third platform (12) is used for fixing a concrete vibrating rod; meanwhile, a scale value is arranged on the third sliding rail (11), and the scale value is used for representing the vibration depth of the vibration rod.

2. A concrete vibrating rod auxiliary vibrating device for construction engineering according to claim 1, characterized in that the auxiliary vibrating device further comprises a first limit bolt (13);

the first limit bolt (13) is arranged on the first platform (5), and the bottom of the first limit bolt (13) is contacted with the first sliding rail (3) by rotating the first limit bolt (13).

3. A concrete vibrating rod auxiliary vibrating device for construction engineering according to claim 1, characterized in that the auxiliary vibrating device further comprises a second limit bolt (14);

the second limit bolt (14) is arranged on the second platform (8), and the bottom of the second limit bolt (14) is contacted with the second sliding rail (7) by rotating the second limit bolt (14).

4. A concrete vibrating rod auxiliary vibrating device for construction engineering according to claim 1, characterized in that the auxiliary vibrating device further comprises a third limit bolt (15);

the third limit bolt (15) is arranged on the third platform (12), and the bottom of the third limit bolt (15) is contacted with the third sliding rail (11) by rotating the third limit bolt (15).

5. A concrete vibrating rod auxiliary vibrating device for construction engineering according to claim 1, characterized in that the auxiliary vibrating device further comprises a fixing clip (17);

the fixing clamp (17) is arranged at a groove of the third platform (12); the groove of the third platform (12) is used for clamping the concrete vibrating rod and fixing the concrete vibrating rod through the fixing clamp (17).

6. The auxiliary vibration device of a concrete vibration rod for construction engineering according to claim 1, wherein a first rotary handle (16) is provided on an end surface of the rotary disk (10);

the position where the first rotary handle (16) is arranged is not coincident with the circle center of the rotary disk (10).

7. The auxiliary vibration device of the concrete vibration rod for the construction engineering according to claim 1, wherein a second rotary handle is arranged on the end face of the gear (6);

the position of the second rotary handle is not coincident with the circle center of the gear (6).

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