CN109457985B - Steel mesh frame ball node installation elevation adjusting device - Google Patents

Abstract

The invention discloses a steel mesh frame ball node installation elevation adjusting device which comprises a horizontal moving rail, a sliding block, a hydraulic motor, an elevation device main body and a control panel, wherein a sliding rail matched with the sliding block is constructed on the upper end face of the horizontal moving rail, side plates connected with the horizontal moving rail are arranged on two sides of the sliding rail, a sliding groove matched with the sliding rail is formed in the middle of the sliding block, an installation groove for installing the hydraulic motor is formed in the top end of the sliding block, a control panel used for being electrically connected with a processor is inlaid on one side of the sliding block, a hydraulic rod is arranged on the top end of the hydraulic motor, the elevation device main body is clamped and installed on the top end of the hydraulic rod, a cylindrical structure matched with a hemispherical groove is formed in the upper end face of the elevation device main body, and a clamping ring is sleeved on the periphery of the elevation device main body. The steel mesh frame ball node installation elevation adjusting device is reasonable in structure, easy to locate the elevation and high in practical value.

Description

Steel mesh frame ball node installation elevation adjusting device

Technical Field

The invention belongs to the technical field of steel mesh frames, and particularly relates to an elevation adjusting device for installing a ball node of a steel mesh frame.

Background

The space structure is formed by connecting a plurality of rods through nodes according to a certain grid form. The device has the advantages of small space stress, light weight, high rigidity, good earthquake resistance and the like; the roof can be used as a roof of buildings such as gymnasiums, movie theaters, exhibition halls, waiting halls, stadium grandstands, canopies, airplane libraries, two-way large-column-space workshops and the like.

The existing steel grid frame building construction is often connected with a rod by using a spherical node, the spherical node cannot be supported by using a common supporting device due to the special surface structure of the spherical node, the positioning of the spherical node in the installation process is particularly important, and the positioning and supporting of the spherical node by using a common jack are inconvenient to adjust.

Disclosure of Invention

The invention aims to provide an elevation adjusting device for installing a steel mesh frame ball node so as to solve the problems in the background art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the steel mesh frame ball node installation elevation adjusting device comprises a horizontal moving rail, sliding blocks, a hydraulic motor, an elevation device main body and a control panel, wherein the upper end face of the horizontal moving rail is provided with a sliding rail matched with the sliding blocks, two sides of the sliding rail are provided with side plates connected with the horizontal moving rail, a sliding groove matched with the sliding rail is formed in the middle of the sliding blocks, and the top end of the sliding blocks is provided with an installation groove for installing the hydraulic motor;

a control panel used for being electrically connected with the processor is embedded and installed on one side of the sliding block, a hydraulic rod is arranged at the top end of the hydraulic motor, and an elevation device main body is installed at the top end of the hydraulic rod in a clamping manner;

the utility model discloses a laser calibration lamp, including elevation device main part, laser calibration lamp, reflecting plate, elevation device main part, the cylindrical structure that the cooperation hemisphere groove has been seted up for the up end to the elevation device main part, and the peripheral cover of elevation device main part is equipped with the joint ring, the hydraulic rod fixed slot that supplies the hydraulic rod cooperation to install is seted up to the bottom of elevation device main part, and installs adsorption mould in the cooperation hemisphere inslot of elevation device main part, the L type light projection pipe that supplies the installation of laser calibration lamp has been seted up in the elevation device main part, the axle center of laser calibration lamp and the axle center mutually perpendicular of elevation device main part, and the corner slant of L type light projection pipe is provided with the reflecting plate.

Preferably, a limiting plate perpendicular to the side plate is constructed at one side, far away from the sliding rail, of the two ends of the side plate, and a group of limiting plates is attached with a transverse distance sensor towards one side of the sliding block.

Preferably, the bottom of joint ring is provided with vertical distance sensor, and vertical distance sensor's height is unanimous with the bottom height of cooperation hemisphere groove.

Preferably, the side matching grooves matched with the side plates are formed in the two sides of the horizontal moving rail, and pulleys abutted with the side plates are embedded and installed on the inner walls of the side matching grooves and the matched surfaces of the side plates.

Preferably, one end of the L-shaped light projection tube faces to the bottom of the matched hemispherical groove, and a light hole adapting to the L-shaped light projection tube is formed in the bottom end of the adsorption mold.

Preferably, the processor arranged in the control panel is electrically connected with the laser calibration lamp and the distance sensor respectively, and the control panel is electrically connected with the hydraulic motor.

The invention has the technical effects and advantages that: the steel mesh frame ball node is provided with the elevation adjusting device, the horizontal displacement of the elevation device body when supporting the ball node is effectively realized through the cooperation of the horizontal moving rail and the sliding block, and the horizontal position of the ball node is effectively positioned through the cooperation of the horizontal distance sensor; the elevation device main body is matched with a hydraulic motor and a hydraulic rod to realize the height adjustment of the ball joint, and is matched with the effective elevation of the longitudinal distance sensor; the adsorption mold is provided with spherical nodes adapting to different diameters, so that the adsorption installation characteristics are convenient to use and replace, and the applicability is strong; the L-shaped light projection tube is matched with the laser calibration lamp, so that the spherical node can be conveniently positioned and used as a visual reference, and the user can conveniently survey and position.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic diagram of a slider structure according to the present invention;

FIG. 3 is a schematic view of the internal structure of the elevation device body of the present invention;

fig. 4 is a schematic diagram of the circuit connection of the present invention.

In the figure: 1 horizontal moving rail, 101 side plate, 102 limiting plate, 2 sliding block, 201 mounting groove, 3 hydraulic motor, 301 hydraulic rod, 4 elevation device main body, 401 cooperation hemisphere groove, 402 hydraulic rod fixed slot, 5 slide rail, 501 spout, 6 side cooperation groove, 601 pulley, 7 adsorption mold, 701 light trap, 8 laser calibration lamp, 801 reflecting plate, 9 joint ring, 901 longitudinal distance sensor, 10 control panel, 11L formula light projection pipe, 12 transverse distance sensor.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention provides a steel mesh frame ball node installation elevation adjusting device as shown in fig. 1-4, which comprises a horizontal moving rail 1, sliding blocks 2, a hydraulic motor 3, an elevation device main body 4 and a control panel 10, wherein the upper end surface of the horizontal moving rail 1 is provided with sliding rails 5 for the sliding blocks 2 to be matched, two sides of each sliding rail 5 are provided with side plates 101 connected with the horizontal moving rail 1, the center of each sliding block 2 is provided with a sliding groove 501 matched with the sliding rail 5, and the top end of each sliding block 2 is provided with an installation groove 201 for the hydraulic motor 3 to be installed;

a control panel 10 for electrically connecting with a processor (an MSP430 type singlechip is selected when the implementation is carried out) is embedded and installed on one side of the sliding block 2, a hydraulic rod 301 is arranged at the top end of the hydraulic motor 3, and an elevation device main body 4 is installed at the top end of the hydraulic rod 301 in a clamping manner;

the elevation device body 4 is a cylindrical structure with a matched hemispherical groove 401 formed in the upper end face, a clamping ring 9 is sleeved on the periphery of the elevation device body 4, a hydraulic rod fixing groove 402 for the hydraulic rod 301 to be matched and installed is formed in the bottom end of the elevation device body 4, an adsorption mold 7 is installed in the matched hemispherical groove 401 of the elevation device body 4, the adsorption mold 7 is of a hemispherical structure with a hemispherical groove formed in the specific implementation, the diameter of a groove is adapted to a spherical node, an L-shaped light projection pipe 11 for installing a laser calibration lamp 8 is formed in the elevation device body 4, the axis of the laser calibration lamp 8 is perpendicular to the axis of the elevation device body 4, and a reflecting plate 801 is obliquely arranged at a corner of the L-shaped light projection pipe 11.

Specifically, a limiting plate 102 perpendicular to the side plate 101 is configured at one side, far away from the sliding rail 5, of the two ends of the side plate 101, a group of limiting plates 102 is provided with a transverse distance sensor 12 towards one side of the sliding block 2 in an attached mode, the bottom end of the clamping ring 9 is provided with a longitudinal distance sensor 901, the height of the longitudinal distance sensor 901 is consistent with the height of the bottom end of the matched hemispherical groove 401, and the transverse distance sensor 12 and the longitudinal distance sensor 901 are LDM301 series distance sensors.

Specifically, the side mating grooves 6 of mating side plates 101 are formed in the two sides of the horizontal moving rail 1, and the pulleys 601 abutting against the side plates 101 are mounted on the surfaces of the inner walls of the side mating grooves 6 and the mating surfaces of the side plates 101 in an embedded mode, and friction between the horizontal moving rail 1 and the side plates 101 is effectively reduced due to the structure of the pulleys 601.

Specifically, one end of the L-shaped light projection tube 11 faces the bottom of the matching hemispherical groove 401, and the bottom end of the adsorption mold 7 is provided with a light hole 701 adapted to the L-shaped light projection tube 11, and the light hole 701 does not block the calibration laser emitted by the laser calibration lamp 8.

Specifically, the processor disposed in the control panel 10 is electrically connected to the laser calibration lamp 8 and the distance sensor, and the control panel 10 is electrically connected to the hydraulic motor 3.

Specifically, this steel mesh frame ball node installation elevation adjusting device just need open laser calibration lamp 8 and remove horizontal migration rail 1 before the use first to the position of installation ball node, install spherical node in adsorption mould 7, adjust hydraulic motor 3 and make hydraulic stem 301 rise, until spherical node reaches the installation height, and show highly and the record by vertical distance sensor 901 cooperation control panel 10, through adjusting slider 2, and cooperate horizontal distance sensor 12 to show horizontal displacement and the record of cooperation control panel 10, until spherical node reaches the mounted position can, this steel mesh frame ball node installation elevation adjusting device, moreover, the steam generator is rational in infrastructure, easily elevation location, higher practical value has.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims (4)

1. The utility model provides a steel mesh frame ball node installation elevation adjusting device, includes horizontal migration rail (1), sliding block (2), hydraulic motor (3), elevation device main part (4) and control panel (10), its characterized in that: the upper end face of the horizontal moving rail (1) is provided with a sliding rail (5) matched with the sliding block (2), two sides of the sliding rail (5) are provided with side plates (101) connected with the horizontal moving rail (1), a sliding groove (501) matched with the sliding rail (5) is formed in the middle of the sliding block (2), and the top end of the sliding block (2) is provided with an installation groove (201) for installing a hydraulic motor (3);

a control panel (10) used for being electrically connected with a processor is embedded and installed on one side of the sliding block (2), a hydraulic rod (301) is arranged at the top end of the hydraulic motor (3), and an elevation device main body (4) is installed at the top end of the hydraulic rod (301) in a clamping manner;

the elevation device comprises an elevation device main body (4), wherein the elevation device main body (4) is of a cylindrical structure with a matched hemispherical groove (401) on the upper end face, a clamping ring (9) is sleeved on the periphery of the elevation device main body (4), a hydraulic rod fixing groove (402) for the matched installation of a hydraulic rod (301) is formed in the bottom end of the elevation device main body (4), an adsorption mold (7) is installed in the matched hemispherical groove (401) of the elevation device main body (4), an L-shaped light projection pipe (11) for the installation of a laser calibration lamp (8) is formed in the elevation device main body (4), the axis of the laser calibration lamp (8) is perpendicular to the axis of the elevation device main body (4), the axis of one section of the L-shaped light projection pipe (11) coincides with the axis of the laser calibration lamp (8), and the axis of the other section of the L-shaped light projection pipe (11) coincides with the axis of the laser calibration lamp main body (4), and a reflecting plate (801) is obliquely arranged at a corner of the L-shaped light projection pipe (11);

a limiting plate (102) perpendicular to the side plate (101) is constructed at one side, far away from the sliding rail (5), of the two ends of the side plate (101), and a transverse distance sensor (12) is attached to one side, facing the sliding block (2), of one group of limiting plates (102);

one end of the L-shaped light projection tube (11) faces to the bottom of the matched hemispherical groove (401), and a light hole (701) adapting to the L-shaped light projection tube (11) is formed in the bottom end of the adsorption mold (7).

2. The steel mesh frame ball node installation elevation adjusting device according to claim 1, wherein: the bottom of joint ring (9) is provided with vertical distance sensor (901), and the height of vertical distance sensor (901) is unanimous with the bottom height of cooperation hemisphere groove (401).

3. The steel mesh frame ball node installation elevation adjusting device according to claim 1, wherein: side matching grooves (6) matched with the side plates (101) are formed in two sides of the horizontal moving rail (1), and pulleys (601) abutted against the side plates (101) are embedded on the matched surfaces of the inner walls of the side matching grooves (6) and the side plates (101).

4. The steel mesh frame ball node installation elevation adjusting device according to claim 1, wherein: the processor arranged in the control panel (10) is electrically connected with the laser calibration lamp (8) and the distance sensor respectively, and the control panel (10) is electrically connected with the hydraulic motor (3).