CN221722330U - A stone splicing frame with stepless angle adjustment - Google Patents

Abstract

The present application discloses a stone splicing frame with stepless angle adjustment; it relates to the technical field of stone curtain wall assembly and comprises a base, on which two support groups for placing stone slab side panels are rotatably connected, the two support groups are symmetrically arranged along the width direction of the base, and a space for placing the stone slab bottom plate and the stone slab skeleton is reserved between the two support groups; the support group comprises two support rods, the two support rods are arranged at intervals along the length direction of the base, the support rods are rotatably connected to the base, and the rotation axis of the support rods is arranged along the length direction of the base; a driving assembly for driving the support rods to rotate is also provided on the base; the present application enables the assembly frame to quickly and accurately assist in completing the assembly of the stone slab and the skeleton through the arrangement of the driving assembly and the support rods.

Description

A stone splicing frame with stepless angle adjustment

Technical Field

The present application relates to the technical field of stone curtain wall assembly, and in particular to a stone splicing frame with stepless angle adjustment.

Background Art

The stone curtain wall adopts a unitized assembly structure, which can save installation time to a great extent during the installation process. The stone panels are connected to the profile skeleton to form a complete unitized stone structure. The stone panels usually include a bottom plate and two stone side plates. After the unitized stone structure is assembled, it is transported to the site for positioning and hanging, realizing a fast construction process.

For some variable-section, multi-angle unitized stone curtain walls, there are higher requirements for their angle splicing accuracy and unit plate forming efficiency. The traditional splicing method of installing profiles first and then installing surface material plates is difficult to meet the rapid construction requirements of such variable-section, multi-angle unitized stone curtain walls. Therefore, we need to find more innovative solutions to improve construction quality and efficiency.

Utility Model Content

In order to quickly and accurately complete the assembly of unit panels, the present application provides a stone splicing frame with stepless angle adjustment.

The present application provides a stone splicing frame with stepless angle adjustment, which adopts the following technical solution:

A stone splicing frame with stepless angle adjustment comprises a base, to which two support groups for placing side panels of a stone plate are rotatably connected, the two support groups are symmetrically arranged along the width direction of the base, and a space for placing a bottom plate and a frame of the stone plate is reserved between the two support groups; the support group comprises two support rods, the two support rods are arranged at intervals along the length direction of the base, the support rods are rotatably connected to the base, and the rotation axis of the support rods is arranged along the length direction of the base; the base is also provided with a driving assembly for driving the support rods to rotate.

By adopting the above technical solution, when prefabricating unit stone panels, the angle of the support rod is first adjusted, and then the side panels of the stone panel are placed on the two support groups respectively, and the bottom panel of the stone panel is placed between the two support groups, and then the profile skeleton is placed between the side panels and the bottom panel and connected to complete the assembly of the unit stone panel; the assembly accuracy and efficiency of the special-shaped unit stone panels are improved.

Optionally, the driving assembly includes a rotating rod and a sliding block, the sliding block is slidably connected to the base along the width direction of the base, the two ends of the rotating rod are respectively rotatably connected to the sliding block and the support rod, and the sliding block slides to drive the support rod to rotate; the base is also provided with a driving member for driving the sliding block to slide.

Optionally, the driving member includes a screw rod, which is rotatably connected to the base, and the rotation axis of the screw rod is arranged along the width direction of the base, and the sliding block is connected to the screw rod through a screw nut.

Optionally, one end of the screw rod extending out of the base is also fixedly connected to a hand wheel, and the hand wheel is rotated to drive the screw rod to rotate.

By adopting the above technical solution, when the angle of the support rod needs to be adjusted, the hand wheel is turned to drive the screw rod to rotate, and the rotation of the screw rod drives the sliding block to slide, thereby driving the rotating rod to rotate, and finally driving the support rod to rotate; at the same time, this driving method does not need to worry about the impact of the plate pressing on the support rod causing the support rod to fall.

Optionally, the base includes two short rods and two long rods, and the long rods and the short rods are alternately connected end to end to form the base, the short rods are arranged along the width direction of the base, and the long rods are arranged along the length direction of the base.

Optionally, the short rod is slidably connected to two adjustment seats along its length direction, the driving assembly and the support rod are both arranged on the adjustment seats, and the short rod is also provided with bolts for limiting the sliding of the adjustment seats; the adjustment seat slides to drive the two support rods on the same short rod to move closer to or away from each other.

By adopting the above technical solution, the position of the adjustment seat is changed, thereby changing the space between the two support rods, so that base plates of different sizes can be placed in the space; this is more beneficial to the splicing adjustment of variable-section stone units.

Optionally, lockable universal wheels are mounted on both ends of the long rod.

By adopting the above technical solution, overall transportation is convenient.

Optionally, the support rod is also provided with a magnetic level ruler for measuring its own angle.

By adopting the above technical solution, the rotation angle of the support rod can be conveniently controlled.

Optionally, a support seat is further provided on the adjustment seat, and two support seats located on the same short rod are used to simultaneously support the stone base plate.

In summary, this application includes the following beneficial technical effects:

1. Stepless angle adjustment. Within the adjustable accuracy range, there is no level for angle adjustment, so the stone splicing angle can be more precise.

2. The screw drive method is adopted to save transmission space, making the overall structure more delicate and more cost-effective.

3. The four drive components are all independent systems, which is particularly beneficial for splicing stones with varying angles.

4. A movable adjustment seat is set to increase the adjustable threshold of the bottom panel width, which is more conducive to the splicing adjustment of variable-section stone units, and the splicing frame can be recycled, which improves efficiency and saves costs.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is an overall structural diagram of a stone splicing frame with stepless angle adjustment according to the present application;

FIG2 is a partial structural diagram of the drive assembly in FIG1 ;

FIG3 is a diagram showing the use of a single splicing frame;

FIG. 4 is a diagram showing the use of multiple sets of splicing frames.

Description of reference numerals:

1. Base; 11. Short rod; 111. Strip hole; 12. Long rod; 121. Universal wheel; 21. Adjustment seat; 211. Bolt; 212. Support seat; 22. Support rod; 221. Level ruler; 23. Rotating rod; 24. Sliding block; 31. Screw rod; 32. Handwheel; 33. Bearing seat; 41. Side panel; 42. Bottom plate; 43. Frame.

DETAILED DESCRIPTION

The present application is further described in detail below in conjunction with Figures 1-4.

The embodiment of the present application discloses a stone splicing frame with stepless angle adjustment. Referring to Figures 1 and 2, the splicing frame includes a base 1, and the base 1 includes two long rods 12 and two short rods 11. The long rods 12 and the short rods 11 are alternately spliced to form a rectangular steel frame; the setting direction of the long rods 12 is the length direction of the base 1; a support group for supporting the side panels 41 of the stone board is symmetrically arranged on the base 1 along its own width direction, and the support group includes two support rods 22 arranged at intervals along the width direction, and the two support rods 22 are respectively rotatably connected to the two short rods 11, and the rotation axis of the support rods 22 is arranged along the length direction of the base 1; the side panels 41 of the stone board are simultaneously overlapped on the two support rods 22 of the same support group; at the same time, a driving component for driving the support rods 22 to rotate is also provided on the short rods 11.

In this embodiment, the driving assembly includes a rotating rod 23 and a sliding block 24. The sliding block 24 is slidably connected to the short rod 11 along the length direction of the short rod 11. The two ends of the rotating rod 23 are respectively rotatably connected to the support rod 22 and the sliding block 24. The sliding of the sliding block 24 can drive the rotating rod 23 to rotate, and the rotation of the rotating rod 23 props up the support rod 22. At the same time, a driving member for driving the sliding block 24 to slide is also provided on the short rod 11.

In this embodiment, the driving member includes a screw rod 31, which is rotatably connected to the short rod 11. Both ends of the screw rod 31 are supported by bearing seats 33. The rotation axis of the screw rod 31 is set along the length direction of the short rod 11. The sliding block 24 is connected to the screw rod 31 through the screw rod 31 nut; the screw rod 31 can drive the sliding block 24 to slide when it rotates; at the same time, in order to facilitate the rotation of the screw rod 31, a hand wheel 32 is fixedly connected to the end of the screw rod 31 extending out of the short rod 11. When the screw rod 31 needs to be rotated, the hand wheel 32 can be manually shaken.

At the same time, two support seats 212 are provided on the short rod 11. The support seats 212 are located between the two support rods 22 on the same short rod 11. The two support seats 212 are used to support the stone bottom plate 42. At the same time, they can also prevent the side plate 41 from being too heavy and causing displacement at the connection between the support rod 22 and the short rod 11.

When assembling the unit stone slab, first rotate the screw rod 31 to drive the support rod 22 to rotate, adjust the angle of the support rod 22, then place the stone slab side panels 41 on the two support groups respectively, and place the stone slab bottom panel 42 between the two support groups, then place the profile frame 43 between the side panels 41 and the bottom panel 42 and connect them to complete the assembly of the unit stone slab.

In order to facilitate determination of the angle of the support rod 22 , a magnetic level ruler 221 is provided on the support rod 22 .

Finally, considering that there are many kinds of specifications of the stone slab bottom plate 42, it is necessary to change the distance between the two support rods 22 in the same group to accommodate stone slab bottom plates 42 of different sizes; therefore, two adjustment seats 21 are slidably connected on the short rod 11 along its own length direction, the support seat 212 is fixedly set on the adjustment seat 21, the support rod 22 is rotatably connected to the adjustment seat 21, the sliding block 24 is slidably connected to the adjustment seat 21, the screw rod 31 is rotatably connected to the adjustment seat 21, and the bearing seat 33 is also set on the adjustment seat 21; at the same time, a strip hole 111 is also opened on the short rod 11, and the adjustment seat 21 limits its own sliding through the bolt 211.

The two adjustment seats 21 can slide to expand or reduce the distance between the two opposite support seats 212, so as to adapt to the stone slab bottom plate 42 placed on the two support seats 212.

Finally, in order to facilitate the overall transportation of the device, lockable universal wheels 121 are provided at both ends of the long rod 12 .

3 and 4 , the implementation principle of a stone splicing frame with stepless angle adjustment according to an embodiment of the present application is as follows: when assembling unit stone panels, loosen the bolt 211 and slide the adjustment seat 21 to adjust the distance between the two support seats 212 on the same short rod 11, and tighten the bolt 211 to limit the position of the adjustment seat 21, then rotate the screw rod 31 to drive the support rod 22 to rotate, and adjust the angle of the support rod 22 with the assistance of the level 221, and then place the stone panel side panels 41 on the two support groups respectively, and place the stone panel bottom panel 42 on the two support seats 212, and then place the profile frame 43 between the side panels 41 and the bottom panel 42 and connect them to complete the assembly of the unit stone panels.

The above are all preferred embodiments of the present application, and the protection scope of the present application is not limited thereto. Therefore, any equivalent changes made according to the structure, shape, and principle of the present application should be included in the protection scope of the present application.

Claims (9)

1. A stone splicing frame with stepless angle adjustment, characterized in that it comprises a base (1), on which two support groups for placing side plates of a stone plate are rotatably connected, the two support groups are symmetrically arranged along the width direction of the base (1), and a space for placing a bottom plate of the stone plate and a stone plate frame is reserved between the two support groups; the support group comprises two support rods (22), the two support rods (22) are arranged at intervals along the length direction of the base (1), the support rods (22) are rotatably connected to the base (1), and the rotation axis of the support rods (22) is arranged along the length direction of the base (1); the base (1) is also provided with a driving assembly for driving the support rods (22) to rotate. 2. A stone splicing frame with stepless angle adjustment according to claim 1, characterized in that: the driving assembly comprises a rotating rod (23) and a sliding block (24), the sliding block (24) is slidably connected to the base (1) along the width direction of the base (1), the two ends of the rotating rod (23) are respectively rotatably connected to the sliding block (24) and the support rod (22), the sliding block (24) slides to drive the support rod (22) to rotate; the base (1) is also provided with a driving member for driving the sliding block (24) to slide. 3. A stone splicing frame with stepless angle adjustment according to claim 2, characterized in that: the driving member includes a screw rod (31), the screw rod (31) is rotatably connected to the base (1), the rotation axis of the screw rod (31) is arranged along the width direction of the base (1), and the sliding block (24) is connected to the screw rod (31) through a screw rod (31) nut. 4. A stone splicing frame with stepless angle adjustment according to claim 3, characterized in that one end of the screw rod (31) extending out of the base (1) is also fixedly connected to a hand wheel (32), and the hand wheel (32) rotates to drive the screw rod (31) to rotate. 5. A stone splicing frame with stepless angle adjustment according to claim 1, characterized in that: the base (1) comprises two short rods (11) and two long rods (12), the long rods (12) and the short rods (11) are spliced alternately end to end to form the base (1), the short rods (11) are arranged along the width direction of the base (1), and the long rods (12) are arranged along the length direction of the base (1). 6. A stone splicing frame with stepless angle adjustment according to claim 5, characterized in that: the short rod (11) is slidably connected with two adjustment seats (21) along its own length direction, the driving assembly and the support rod (22) are both arranged on the adjustment seat (21), and the short rod (11) is also provided with a bolt (211) for limiting the sliding of the adjustment seat (21); the adjustment seat (21) slides to drive the two support rods (22) on the same short rod (11) to move closer to or away from each other. 7. A stone splicing frame with stepless angle adjustment according to claim 5, characterized in that both ends of the long rod (12) are equipped with lockable universal wheels (121). 8. A stone splicing frame with stepless angle adjustment according to claim 5, characterized in that: the support rod (22) is also provided with a magnetic level (221) for measuring its own angle. 9. A stone splicing frame with stepless angle adjustment according to claim 6, characterized in that: a support seat (212) is also provided on the adjustment seat (21), and the two support seats (212) located on the same short rod (11) are used to simultaneously support the stone bottom plate (42).