CN218985208U - Movable beam manufacturing pedestal for beam field - Google Patents

Abstract

The utility model relates to a beam field movable beam manufacturing pedestal, which comprises a foundation base, two guide rails arranged along the length direction of the foundation base and a rack arranged on the guide rails, wherein two rows of rollers respectively matched with the two guide rails are arranged on the rack; two energized square tubes are arranged on the foundation base along the length direction of the foundation base, two sliding rods are arranged on the rack in a vertically free sliding mode, and copper plates which are in contact with the upper surface of the square tubes are arranged at the bottom ends of the sliding rods; the copper plate is connected with a speed reducing motor arranged on the frame through a wire, and the speed reducing motor drives the roller to rotate. The beam field movable beam manufacturing pedestal provided by the utility model is simple and convenient to operate, current is provided through the square tube, the speed reducing motor is adopted to drive the idler wheels to replace the hydraulic pump station for driving, the conveying efficiency of the precast beam is improved, the energy consumption is greatly reduced, and the service life of the beam manufacturing pedestal is greatly prolonged.

Description

Movable beam manufacturing pedestal for beam field

Technical Field

The utility model relates to a beam field movable beam manufacturing pedestal, and particularly belongs to the technical field of beam manufacturing production equipment.

Background

The prefabricated beam is prefabricated by a factory and then transported to a construction site to be installed and fixed according to the position of the design requirement. The structure of precast beam includes T roof beam and case roof beam, and the manufacturing of precast beam is through die block subassembly, side form subassembly and end form subassembly enclosure into the model space of precast beam in pouring the district, and to model space pouring concrete again, after the concrete solidification is accomplished, manually demolish side form subassembly and end form subassembly, to the precast beam that the volume is less, can transport precast beam hoist and mount to maintenance district maintenance or deposit the district through the crane and deposit, but can' T transport through the crane to the precast beam that the volume is great, need transport precast beam through the removal pedestal. Because the precast beam needs the distance of transportation to be far away, current removal pedestal carries through hydraulic roller, needs the pump station to provide power, and the pump station needs to follow the removal of removal pedestal, the operation is inconvenient. Aiming at the problems, the utility model provides the beam field movable beam manufacturing pedestal which is simple and convenient to operate, high in conveying efficiency, long in service life and stable in conveying of the precast beam.

Disclosure of Invention

The utility model aims to solve the technical problem of providing the beam field movable beam manufacturing pedestal which is simple and convenient to operate, high in conveying efficiency, long in service life and stable in conveying of the precast beam.

In order to solve the problems, the utility model adopts the following technical scheme:

the movable beam manufacturing pedestal for the beam field comprises a foundation seat, two guide rails arranged along the length direction of the foundation seat and a frame arranged on the guide rails, wherein two rows of rollers respectively matched with the two guide rails are arranged on the frame; two energized square tubes are arranged on the foundation base along the length direction of the foundation base, two sliding rods are arranged on the rack in a vertically free sliding mode, and copper plates which are in contact with the upper surface of the square tubes are arranged at the bottom ends of the sliding rods; the copper plate is connected with a speed reducing motor arranged on the frame through a wire, and the speed reducing motor drives the roller to rotate.

As one implementation mode of the utility model, the gear motor is a double-output-shaft motor, two output shafts of the gear motor are respectively fixedly provided with a pinion, the pinion is meshed with a large gear, and the large gear and the roller are coaxially and fixedly arranged together.

As an implementation mode of the utility model, the roller is arranged on a rotating shaft through a bearing, the rotating shaft is fixedly arranged on a mounting frame, and the mounting frame is fixedly arranged on two sides of the frame; the gear wheel is sleeved on the rotating shaft, and is positioned on the inner side of the roller and connected with the roller through a connecting bolt.

As one implementation mode of the utility model, the outer side of the roller is provided with an end cover, and an oil seal is arranged between the end cover and the rotating shaft.

As an embodiment of the present utility model, the pinion and the large gear are disposed in a horizontal direction, thereby reducing the overall height of the frame.

As one embodiment of the utility model, one side of the square tube is provided with a copper bar, so as to reduce the loss of electric energy in the process of transmitting the electric energy on the square tube.

As one embodiment of the present utility model, a transformer is provided on each section of the square tube to increase the voltage lost on the square tube.

As one embodiment of the present utility model, an insulating sheet and an insulating plate are respectively provided between the copper plate and the slide bar, and between the square tube and the base.

As one implementation mode of the utility model, the top end of the frame is provided with the second connecting rod and the connecting nut, and the side die assembly is connected with the frame through the second connecting rod and the connecting nut, so that the beam making pedestal is prevented from moving in the pouring process.

As one implementation mode of the utility model, the guide rail is an I-shaped steel and is arranged on the foundation base through a limiting plate and embedded bolts.

The beneficial effects of adopting above-mentioned technical scheme to produce lie in:

the beam field movable beam manufacturing pedestal provided by the utility model is simple and convenient to operate, current is provided through the square tube, the speed reducing motor is adopted to drive the idler wheels to replace the hydraulic pump station for driving, the conveying efficiency of the precast beam is improved, the energy consumption is greatly reduced, and the service life of the beam manufacturing pedestal is greatly prolonged. The gear motor is a double-output-shaft motor, power transmission is carried out between the gear motor and the idler wheels through a horizontally arranged large gear and a small gear, the total height of the whole girder manufacturing pedestal is reduced, the gravity center of the precast girder is reduced, and conveying is stable.

Drawings

Fig. 1 is a schematic view of the structure of the girder and girder-making stand of the present utility model.

Fig. 2 is a schematic front view of the beam-making stand according to the present utility model.

Fig. 3 is a schematic diagram of the front view of the internal structure of the girder fabricating pedestal in the present utility model.

Fig. 4 is a schematic top view of the girder fabricating base according to the present utility model.

Wherein: 1 ground, 2 walking grooves, 3 foundation seats, 4 guide rails, 5 racks, 6 rollers, 7 square tubes, 8 copper bars, 9 copper plates, 10 insulating sheets, 11 sliding bars, 12 large gears, 13 small gears, 14 rotating shafts, 15 output shafts, 16 speed reduction motors, 17 mounting frames, 18 side mold assemblies, 19 connecting rods I, 20 connecting rods II, 21 precast beams, 22 end covers, 23 oil seals, 24 connecting bolts, 25 insulating plates, 26 limiting plates and 27 embedded bolts.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the present utility model will be clearly and completely described in connection with the following specific embodiments.

The beam field movable beam making pedestal shown in the figures 1-4 comprises a foundation base 3, two guide rails 4 arranged along the length direction of the foundation base, and a frame 5 arranged on the guide rails 4, wherein two rows of rollers 6 respectively matched with the two guide rails 4 are arranged on the frame 5; two energized square tubes 7 are arranged on the foundation base 3 along the length direction of the foundation base, two sliding rods 11 are arranged on the frame 5 in a vertically free sliding mode, and copper plates 9 which are in contact with the upper surfaces of the square tubes 7 are arranged at the bottom ends of the sliding rods 11; the copper plate 9 is connected with a speed reduction motor 16 arranged on the frame 5 through a wire, and the speed reduction motor 16 drives the roller 6 to rotate. After the precast beam 21 is demolded, the beam manufacturing pedestal drives the precast beam 21 to move along the guide rail 4 for conveying. The beam field movable beam manufacturing pedestal is easy and convenient to operate, current is provided through the square tube 7, the speed reducing motor 16 is adopted to drive the idler wheels 6 to replace the hydraulic pump station for driving, the conveying efficiency of the precast beam 21 is improved, the energy consumption is greatly reduced, and the service life of the beam manufacturing pedestal is greatly prolonged.

In this embodiment, the gear motor 16 is a dual-output shaft motor, two output shafts 15 of the dual-output shaft motor are respectively and fixedly provided with a pinion 13, the pinion 13 is meshed with a large gear 12, and the large gear 12 and the roller 6 are coaxially and fixedly arranged together. The gear motor 16 is a double-output shaft motor, power transmission is carried out between the gear motor 16 and the idler wheels 6 through the horizontally arranged large gear 12 and small gear 13, the total height of the whole beam making pedestal is reduced, the center of gravity of the precast beam 21 is reduced, and the conveying is more stable.

The roller 6 is arranged on the rotating shaft 14 through a bearing, the rotating shaft 14 is fixedly arranged on the mounting frame 17, and the mounting frame 17 is fixedly arranged on two sides of the frame 5; the large gear 12 is sleeved on the rotating shaft 14, and the large gear 12 is positioned on the inner side of the roller 6 and is connected with the roller 6 through a connecting bolt 24. An end cover 22 is arranged on the outer side of the roller 6, and an oil seal is arranged between the end cover 22 and the rotating shaft 14.

As a further optimization, a copper bar 8 (copper bar) is arranged on one side of the square tube 7 along the length direction, so as to reduce the loss of electric energy in the process of transmitting the electric energy on the square tube 7. A transformer is arranged on the square tube 7 at intervals to increase the voltage lost on the square tube 7.

As a further optimization, an insulating sheet 10 and an insulating plate 25 are respectively arranged between the copper plate 9 and the slide rod 11 and between the square tube 7 and the foundation base 3.

The side die assembly 18 is connected with the frame 5 through the connecting rod II 20 and the connecting nut, and the beam making pedestal is prevented from moving in the pouring process. When the precast beam 21 is poured, the two side die assemblies 18 are connected together through a connecting rod I19 and a connecting nut.

As a further optimization, the guide rail 4 is an i-shaped steel, and is mounted on the foundation base 3 through a limiting plate 26 and an embedded bolt 27.

In this embodiment, the sliding rod 11 is only slidably disposed on the frame 5, and under the action of gravity, the copper plate 9 naturally contacts with the upper surface of the square tube 7. As a further optimization, a spring is arranged between the sliding rod 11 and the frame 5, so that the lower end of the sliding rod 11 is pressed on the square tube 7.

Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art may modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some technical features thereof; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. The utility model provides a portable system roof beam pedestal in roof beam field which characterized in that: the device comprises a foundation seat, two guide rails arranged along the length direction of the foundation seat and a rack arranged on the guide rails, wherein two rows of rollers respectively matched with the two guide rails are arranged on the rack; two energized square tubes are arranged on the foundation base along the length direction of the foundation base, two sliding rods are arranged on the rack in a vertically free sliding mode, and copper plates which are in contact with the upper surface of the square tubes are arranged at the bottom ends of the sliding rods; the copper plate is connected with a speed reducing motor arranged on the frame through a wire, and the speed reducing motor drives the roller to rotate.

2. A beam field mobile beam forming stand according to claim 1, wherein: the gear motor is a double-output-shaft motor, a pinion is fixedly arranged on two output shafts of the gear motor respectively, the pinion is meshed with a large gear, and the large gear and the roller are coaxially and fixedly arranged together.

3. A beam field mobile beam forming stand according to claim 2, wherein: the rollers are arranged on a rotating shaft through bearings, the rotating shaft is fixedly arranged on a mounting frame, and the mounting frame is fixedly arranged on two sides of the frame; the gear wheel is sleeved on the rotating shaft, and is positioned on the inner side of the roller and connected with the roller through a connecting bolt.

4. A beam field mobile beam forming stand according to claim 3, wherein: an end cover is arranged on the outer side of the roller, and an oil seal is arranged between the end cover and the rotating shaft.

5. A beam field mobile beam forming stand according to claim 2, wherein: the pinion and the bull gear are disposed in a horizontal direction to reduce the overall height of the frame.

6. A beam field mobile beam forming stand according to any one of claims 1-5, wherein: and one side of the square tube is provided with a copper bar for reducing the loss of electric energy in the process of transmitting the electric energy on the square tube.

7. A beam field mobile beam forming stand according to claim 6, wherein: and a transformer is arranged on each section of the square tube and is used for improving the voltage lost on the square tube.

8. A beam field mobile beam forming stand according to claim 7, wherein: and an insulating sheet and an insulating plate are respectively arranged between the copper plate and the sliding rod and between the square tube and the foundation base.

9. A beam field mobile beam forming stand according to claim 1, wherein: the side die assembly is connected with the frame through the connecting rod II and the connecting nut, and the beam making pedestal is prevented from moving in the pouring process.

10. A beam field mobile beam forming stand according to claim 9, wherein: the guide rail is I-shaped steel and is installed on the foundation base through a limiting plate and embedded bolts.

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