CN112982803A - Shape suspended ceiling structure of preapring for an unfavorable turn of events - Google Patents

Abstract

The application relates to an anti-deformation suspended ceiling structure, which comprises a plurality of rows of bottom keels distributed at intervals, expansion bolts penetrating through the bottom keels and used for being connected with a floor slab, hanging rods connected to the expansion bolts, and a top plate assembly connected to the hanging rods; the end keel includes a plurality of sections coaxial coupling's unit fossil fragments in proper order, and the unit fossil fragments include the base of being connected with the floor and connect in the supplementary positioning seat that the base deviates from floor one side, supplementary positioning seat passes through the relative level of axis of rotation and rotates to be connected on the base, expansion bolts is coaxial to be worn to locate in the axis of rotation, offer the auxiliary hole that is used for fixing a position adjacent fossil fragments unit on the supplementary positioning seat. This application has and reduces ink line lofting quantity to the effect of ceiling suspended ceiling structure construction.

Description

Shape suspended ceiling structure of preapring for an unfavorable turn of events

Technical Field

The application relates to the technical field of building interior decoration installation, in particular to an anti-deformation suspended ceiling structure.

Background

At present, a suspended ceiling is one of important components of interior decoration, and is mainly used for shielding and connecting a floor slab to lower electric appliances, ventilation air conditioners, communication, fire prevention, alarm pipelines and the like.

The existing ceiling structure installation method comprises the following steps: according to the design, the two length direction's in length direction's middle part both ends are fixed a position in proper order, laying-out and installation jib, and the jib adopts expansion bolts to fix.

Then, a main keel is installed below the suspension rod, and the length of the main keel is parallel to the width direction of the floor slab. And an auxiliary keel vertical to the different surface of the main keel axis is arranged below the main keel.

And then, a bottom plate for forming shielding is fixed on the lower surface of the auxiliary keel.

And finally, plastering the lower surface of the bottom plate.

Referring to fig. 1, during positioning and lofting, a field worker bolches a vertical staggered longitudinal ink line 3 and a transverse ink line 2 on the lower surface of a floor slab 1, and then drills and installs expansion bolts at intersection points of the longitudinal ink line 3 and the transverse ink line 2.

With respect to the related art in the above, the inventors consider that: in order to ensure the lofting precision of the suspender, criss-cross ink lines need to be lofted one by one on the lower surface of the floor slab, which is troublesome.

Disclosure of Invention

In order to facilitate the construction suspended ceiling structure, this application provides a shape suspended ceiling structure of preapring for an unfavorable turn of events.

The application provides a pair of shape suspended ceiling structure of preapring for an unfavorable turn of events adopts following technical scheme:

the utility model provides an anti-deformation suspended ceiling structure, its includes the end keel that a plurality of rows of interval distribute, wears to locate the expansion bolts who is used for being connected with the floor on the end keel, connects the jib on expansion bolts to and connect the roof subassembly on the jib. The end keel includes a plurality of sections coaxial coupling's unit fossil fragments in proper order, and the unit fossil fragments include the base of being connected with the floor and connect in the supplementary positioning seat that the base deviates from floor one side, supplementary positioning seat passes through the relative level of axis of rotation and rotates to be connected on the base, expansion bolts is coaxial to be worn to locate in the axis of rotation, offer the auxiliary hole that is used for fixing a position adjacent fossil fragments unit on the supplementary positioning seat.

Through adopting above-mentioned technical scheme, end fossil fragments, expansion bolts, jib and roof subassembly form the furred ceiling structure. The base of the unit keel is used for being connected with a floor slab, the auxiliary positioning seat on the unit keel is rotated, the axis of the auxiliary positioning seat is perpendicular to the axis of the base in a non-coplanar mode, and the expansion bolt position of the adjacent bottom keel is located through the auxiliary hole in the auxiliary positioning seat. Compare in coming out with the full ink line lofting of vertically and horizontally staggered, this application can reduce the lofting quantity of ink line, reduces lofting engineering volume to ceiling suspended ceiling structure construction.

Optionally, a sliding groove is formed in the auxiliary positioning seat, the sliding groove is parallel to the length direction of the auxiliary positioning seat, a positioning block is connected in the sliding groove in a sliding mode, the auxiliary hole is vertically communicated with the positioning block, a vertical through hole is formed in the bottom of the sliding groove, and the auxiliary hole vertically corresponds to the through hole.

Through adopting above-mentioned technical scheme, the auxiliary hole is seted up in the location soon, moves in the spout through the locating piece, and the hole that stretches out that link up so that on-the-spot personnel adopt the marker pen to pass and contact with the floor lower surface, thereby so that fix a position, loft the expansion bolts position on the adjacent end fossil fragments on the floor.

Optionally, the lower surface of the auxiliary positioning seat is provided with a scale for displaying the distance between the axis of the auxiliary hole and the axis of the rotating shaft, one side of the positioning block, which deviates from the floor slab, is fixedly connected with a pointer which is arranged along the radial direction of the auxiliary hole, one end of the pointer in the length direction points to the axis of the auxiliary hole, and the other end of the pointer which is opposite to the pointer points to the scale.

Through adopting above-mentioned technical scheme, the precision that positioning seat removed can be improved to scale and pointer.

Optionally, an observation groove used for aligning a transverse ink line formed by lofting is further formed in the base, the observation groove is vertically arranged in a penetrating mode, and when the axis of the base is parallel to the axis of the auxiliary positioning seat, the observation groove is vertically communicated with the extending hole.

Through adopting above-mentioned technical scheme, the observation tank is used for observing the vertical coincidence condition between base axis and the horizontal ink line to improve the precision of base installation.

Optionally, the two ends of the observation groove parallel to the length direction of the base are fixedly connected with aligning plates used for attaching ink lines, and the aligning plates are vertically arranged.

By adopting the technical scheme, the aligning plate can abut against the floor slab when the upper surface of the base is attached to the floor slab, and when the top end of the aligning plate shields the transverse ink line part, the base is axially positioned below the transverse ink line so as to improve the mounting precision of the base.

Optionally, one axial end of the base is fixedly connected with a convex block, the other axial end of the base is provided with a groove, and the convex blocks and the grooves of two adjacent bases on the same bottom keel are in insertion fit.

Through adopting above-mentioned technical scheme, the lug and the recess grafting cooperation of two adjacent bases for the base of installing earlier can provide the location for the base of back installation, thereby is convenient for improve base installation accuracy.

Optionally, the base is provided with two limiting grooves, the two limiting grooves are spaced along the length direction of the base, and the two limiting grooves are respectively located on two sides of the rotating shaft; when the auxiliary positioning seat positions the keel unit on the adjacent bottom keel, the limiting part can be detachably connected in the limiting groove, the limiting part comprises a limiting insertion plate with one end extending into the limiting groove, and two opposite sides of the limiting insertion plate are respectively abutted against two sides of the auxiliary positioning seat.

Through adopting above-mentioned technical scheme, when the spacing picture peg of locating part can be at the expansion bolts position on the adjacent bottom keel of auxiliary positioning seat location, the rotation of auxiliary positioning seat can be retrained to two spacing picture pegs to the stability can of auxiliary positioning seat when the guarantee location improves the precision of location, laying-out.

Optionally, the base is further provided with an additional hole which is vertically through, a screw rod penetrates through the additional hole, and one end of the screw rod extends into the floor slab and is fixed with the floor slab; when the auxiliary positioning seat is positioned, the axis of the auxiliary positioning seat is parallel to the axis of the base, and one end of the screw rod, which deviates from the floor slab, vertically penetrates through the auxiliary hole of the positioning block.

Through adopting above-mentioned technical scheme, after adjacent expansion bolts position location, lofting are accomplished, wear to establish the screw rod at additional hole and supplementary hole are coaxial, the shank of bolt can retrain the rotation of auxiliary positioning seat to improve the wholeness ability of unit fossil fragments after adjacent expansion bolts position location, lofting are accomplished.

Optionally, an anti-falling rod is arranged between the screw rod and the main keel of the top plate assembly.

Through adopting above-mentioned technical scheme, prevent weighing down the pole at the installation between the main joist of screw rod and roof subassembly, prevent weighing down the pole and can will alleviate the load of jib to prevent that the load that the weighing down pole bore will transmit for the screw rod, transmit the floor by the screw rod again, thereby reduce the connection stability ability that improves the roof subassembly.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the auxiliary positioning seats on the unit keels are rotated, so that the axes of the auxiliary positioning seats are perpendicular to the axes of the bases in a different surface mode, and the expansion bolts of the adjacent bottom keels are positioned through the auxiliary holes in the auxiliary positioning seats, so that the lofting quantity of ink lines is reduced, and the lofting engineering quantity is reduced, and the ceiling structure construction is facilitated;

2. the top end of the alignment plate shields the part of the transverse ink line, so that the axis of the base is positioned below the transverse ink line, and the mounting precision of the base is improved;

3. the anti-falling rod can reduce the load of the suspender, thereby reducing and improving the connection stability of the top plate component.

Drawings

Fig. 1 is a schematic structural view of a prior art suspended ceiling structure after lofting.

Fig. 2 is a schematic view of the overall operating condition structure of the embodiment of the present application.

Fig. 3 is a schematic view of a working condition structure in the unit keel auxiliary positioning of the embodiment of the application.

Fig. 4 is a schematic view of the connection structure of the hanger bar and the unit keel in the embodiment of the application.

Fig. 5 is a schematic structural diagram of the working condition of the unit keel in the reset state in the embodiment of the application.

FIG. 6 is a schematic structural view of the working condition of the anti-drop bar according to the embodiment of the present application.

Fig. 7 is a schematic structural diagram of a limiting insertion plate according to an embodiment of the present application.

Description of reference numerals: 1. a floor slab; 2. transverse ink lines; 3. longitudinal ink lines; 4. a bottom keel; 5. an expansion bolt; 6. a boom; 7. a top plate assembly; 8. a base; 9. an auxiliary positioning seat; 10. a rotating shaft; 11. a bump; 12. a groove; 13. an observation tank; 14. an alignment plate; 15. an additional aperture; 16. a limiting groove; 17. an arc groove; 18. a limiting inserting plate; 19. a card slot; 20. a resilient compression member; 21. a snap-fit rib; 22. an auxiliary body; 23. positioning blocks; 24. a chute; 25. an outlet hole; 26. a pointer; 27. a screw; 28. preventing falling down the rod; 29. a rod body; 30. a first attachment plate; 31. a second attachment panel; 32. a bolt member; 33. and (4) auxiliary holes.

Detailed Description

The present application is described in further detail below with reference to figures 2-7.

Referring to fig. 2 and 3, a plurality of parallel transverse ink lines 2 are set out on the lower surface of a floor slab 1 in advance, a longitudinal ink line 3 which is vertically crossed with the transverse ink line 2 is popped up in the middle of the transverse ink line 2 in the length direction, and the intersection point of the transverse ink line 2 and the longitudinal ink line 3 in the middle is the middle of the lower surface of the floor slab and is the installation position of a first unit keel.

The embodiment of the application discloses shape ceiling suspended ceiling structure of preapring for an unfavorable turn of events. Referring to fig. 2 and 3, the suspended ceiling structure includes a plurality of rows of bottom joists 4 connected to the lower surface of the floor slab 1 and having axes parallel to the height of the ink lines, expansion bolts 5 inserted into the bottom joists 4, suspension rods 6 connected to the expansion bolts 5, and a ceiling assembly 7 connected to the suspension rods 6. The top plate assembly 7 comprises a main keel connected to one side of the bottom end of the suspender 6, a false keel connected to the bottom end of the main keel and a decorative bottom plate connected to the bottom end of the false keel.

In fig. 3 and 4, the bottom keel 4 comprises a plurality of keel units which are coaxially connected in sequence. The keel unit comprises a base 8 with the upper surface attached to the floor slab 1 and an auxiliary positioning seat 9 attached to the lower surface of the base 8. A vertical rotating shaft 10 penetrates through the auxiliary positioning seat 9. Through the rotating shaft 10, the auxiliary positioning seat 9 is horizontally and rotatably connected to the lower surface of the base 8 relative to the base 8. The expansion bolt 5 vertically and coaxially penetrates through the rotating shaft 10.

Referring to fig. 3 and 5, the auxiliary positioning seat 9 is provided with an auxiliary hole 33 which is vertically penetrated. And rotating the auxiliary positioning seat 9 to enable the axis of the auxiliary positioning seat 9 to be vertical to the different surface of the transverse ink line 2, vertically projecting the auxiliary hole 33 on the transverse ink line 2, wherein the position of the auxiliary hole 33 is the position of the expansion bolt 5 of the adjacent bottom keel 4, and the unit keel is in an auxiliary positioning state at the moment. Compare in the whole back of horizontal ink line 2 of lofting play, lofting play out all vertical ink line 3 again, this application can reduce vertical ink line 3's lofting quantity to installation ceiling furred ceiling structure.

When the unit keel is in the auxiliary positioning state, the base 8 can be detachably connected with a limiting part for limiting the rotation of the auxiliary positioning seat 9, and the limiting part can improve the stability of the unit keel at the auxiliary positioning time of the auxiliary positioning seat 9, so that the positioning precision is improved.

The site personnel can use a drilling machine to drill holes in the floor slab 1 along the axial direction of the auxiliary holes 33 to form mounting holes for mounting the expansion bolts 5. After the installation hole is formed, the limiting part is detached, the axis of the auxiliary positioning seat 9 is parallel to the axis of the base 8, and at the moment, the unit keel is in a reset state.

Referring to fig. 4 and 5, the base 8 is rectangular, a protrusion 11 is fixedly connected to one axial end of the base 8, and a groove 12 is formed in the other axial end of the base 8. Vertical through observation groove 13 has still been seted up to base 8's lower surface, and the length direction setting of the parallel base 8 in observation groove 13, the equal vertical alignment board 14 of fixedly connected with in the axial both ends of the parallel base 8 in observation groove 13, the top of alignment board 14 and base 8's upper surface parallel and level.

When the base 8 is attached to the floor slab 1, the top end of the alignment plate 14 is attached to the lower surface of the floor slab 1, and the alignment plate 14 is aligned to shield the portion of the transverse ink line 2, thereby improving the installation accuracy of the base 8.

The upper surface of the base 8 is also coated with an adhesive (not shown) for adhesive attachment to the floor 1. The lower surface of the base 8 is further provided with an additional hole 15, the additional hole 15 is located in the middle of the length direction of the base 8, and the axis of the additional hole 15 is perpendicularly intersected with the axis of the observation groove 13.

Two adjacent bases 8 on the same bottom keel 4 are matched with the convex blocks 11 and the grooves 12 in an inserting manner, so that the mounting precision of the bases 8 is improved.

Referring to fig. 5 and 6, the lower surface of the base 8 and the two sides of the rotating shaft 10 are both provided with a limiting groove 16, and the two limiting grooves 16 are distributed in parallel with the length direction of the base 8. The limiting groove 16 is long, and the length direction of the limiting groove 16 is vertical to the axis of the base 8. The wall of the limit groove 16 is provided with an arc groove 17.

Referring to fig. 5 and 7, the limiting member includes a limiting insertion plate 18, a clamping groove 19 is formed in one side of the limiting insertion plate 18 in the thickness direction, an elastic expansion member 20 and a clamping rib 21 fixedly connected to the elastic expansion member 20 are fixedly connected to the clamping groove 19, and the elastic expansion member 20 is an expansion spring. One side that the cross section of joint rib 21 deviates from expanding spring is circular-arcly, and when the locating part stretched into spacing groove 16 in, elastic expansion spare 20 in the draw-in groove 19 will take place elastic shrinkage deformation and produce reaction force for joint rib 21 is circular-arcly one side and can stretch into to circular arc groove 17 in.

When the unit keel is in the auxiliary positioning state, the limiting parts are respectively arranged in the limiting grooves 16 at two sides of the rotating shaft 10, at this time, the clamping ribs 21 correspondingly extend into the arc grooves 17, two opposite sides of the two limiting parts are respectively attached to two sides of the auxiliary positioning seat 9, and the axis of the auxiliary positioning seat 9 is perpendicular to the axis of the base 8 in a non-coplanar manner. The locating part can make the unit fossil fragments be in the assistance-localization real-time state fast to through the rotation of two locating parts restraint assistance-localization real-time seat 9, reduce the probability that assistance-localization real-time seat 9 rocked, thereby guarantee the horizontal ink line 2 of 33 vertical alignments of auxiliary hole.

After the positioning is completed, the limiting part is manually taken down so as to reduce the probability that the limiting part interferes with the rotation of the auxiliary positioning seat 9.

Referring to fig. 3 and 5 again, the auxiliary positioning seat 9 includes an auxiliary body 22 and a positioning block 23, a sliding groove 24 is formed in one side of the auxiliary body 22 away from the floor slab 1, a cross section of the sliding groove 24 is T-shaped, and a length direction of the sliding groove 24 is parallel to a length direction of the auxiliary body 22. The lower surface of the auxiliary body 22 is also provided with a scale (not shown), which is provided along the entire length of the slide groove 24.

The top end groove wall of the sliding groove 24 is provided with a vertically through extending hole 25, the extending hole 25 is in a long strip shape, and the length direction of the extending hole 25 is parallel to the length direction of the sliding groove 24. The positioning block 23 is connected in the sliding groove 24 in a sliding manner, and the auxiliary hole 33 is vertically arranged on the positioning block 23 in a penetrating manner.

One side of the positioning block 23, which is far away from the floor slab 1, is connected with a pointer 26, one end of the pointer 26 points to the auxiliary hole 33, the other needle point of the pointer 26 points to the scale, and the axis of the pointer 26 is perpendicular to the different surface of the sliding groove 24 in the length direction.

When the unit keel is in the auxiliary positioning state, the positioning block 23 is made to slide in the sliding groove 24, so that the extension of the axis of the auxiliary hole 33 is projected on the adjacent transverse ink line 2 for positioning.

When the unit keel is in a reset state, the positioning block 23 slides in the sliding groove 24, and the top end of the extending hole 25 is coaxially communicated with the bottom end of the additional hole 15 on the base 8. The screw rods 27 are coaxially arranged in the additional holes 15 and the auxiliary holes 33 in a penetrating mode, the top ends of the screw rods 27 extend into the floor slab 1 and are fixedly connected with the floor slab, the bottom ends of the screw rods 27 are lower than the unit keels, and external threads are formed in the side portions of the bottom ends of the screw rods 27.

Referring to fig. 6, a drop prevention bar 28 is further connected between the unit keel and the top plate assembly 7. The anti-falling rod 28 comprises a rod body 29, a first attaching plate 30 and a second attaching plate 31. The axis of the rod 29 is arranged obliquely.

The upper surface of first attaching plate 30 and the lower surface laminating of locating piece 23, screw rod 27 wears to locate on first attaching plate 30 to the bottom of first attaching plate 30 is provided with the lock nut that is used for retraining first attaching plate 30 vertical movement.

The lower surface of second rigging board 31 and the main joist laminating of roof subassembly 7 to wear to be equipped with bolt piece 32 on the second rigging board 31, bolt piece 32 passes second rigging board 31 and stretches into to main joist fixed connection. The second abutting plate 31 is fixedly connected with the main keel through a bolt piece 32.

The anti-falling rod 28 positioned between the top plate component 7 and the positioning block 23 can share and lighten the load of the suspender 6, and the overall strength of the suspended ceiling is improved, so that the probability of settlement and falling of the suspended ceiling structure is reduced.

The implementation principle of the ceiling suspended ceiling structure of preapring for an unfavorable turn of events shape of the embodiment of this application is: the installation method of the ceiling structure comprises the following steps: and S1, performing preliminary lofting, namely firstly releasing the transverse ink lines 2 and the longitudinal ink lines 3 positioned in the middle of the length direction of the transverse ink lines 2 from the lower surface of the floor slab 1.

And S2, installing the bottom keel 4. S2-1, installing a first unit keel, and installing a first expansion bolt 5 at the position where a transverse ink line 2 and a longitudinal ink line 3 in the middle of a floor slab 1 are intersected firstly. Meanwhile, the hanger rod 6 is inserted into the rotation shaft 10 of the unit keel.

S2-2, fixing the base 8 of the first unit keel. The unit keel is in the reset state, the aligning plate 14 shields the transverse ink line 2, and the axis of the base 8 is positioned below the transverse ink line 2. Before the alignment, the adhesive is coated on both sides of the cross ink line 2 to be aligned.

And S2-3, assisting positioning. The position of the expansion bolt 5 on the adjacent transverse ink line 2 is positioned. The auxiliary positioning seat 9 is rotated to enable the axis of the auxiliary positioning seat 9 to be perpendicular to the opposite surface of the axis of the base 8, and a limiting part is arranged in the limiting hole to restrict the rotation of the auxiliary positioning seat 9 during positioning. Then, the positioning block 23 is moved, when the extension of the axis of the auxiliary hole 33 on the positioning block 23 is located at the adjacent transverse ink line 2, the reading of the pointer 26 pointing to the scale and the interval between the pointer and the adjacent transverse ink line 2 on the design drawing are checked, so as to reduce the probability that the transverse ink line 2 lofting deviation causes the installation deviation of the suspender 6. When the absolute value of the error between the reading pointed by the pointer 26 and the space size on the design drawing is less than 5mm, the cross ink line 2 which is already set out can be directly referred to so as to quickly position the expansion bolt 5.

And S2-4, resetting. After the positioning is finished, firstly, holes are drilled along the axis of the additional hole 15, and then the auxiliary positioning seat 9 is rotated, so that the axis of the auxiliary positioning seat 9 is parallel to the axis of the base 8. Then, the positioning block 23 is moved to make the auxiliary hole 33 coaxial with the additional hole 15, and then the screw 27 is installed by means of bar planting.

And S2-5, forming a first-way bottom keel 4. The two sides in the length direction of the first unit cage bone are sequentially provided with the remaining unit keels of the bottom keel 4. When the expansion bolt is installed, the convex block 11 is firstly inserted and matched with the groove 12, then the alignment plate 14 is used for aligning the horizontal ink line 2, and finally the rotation shaft 10 is used for positioning and installing the expansion bolt 5.

And S3, installing the rest bottom keel 4. The two sides of the width direction of the received bottom keel 4 are sequentially provided with the residual bottom keel 4. The installation of the unit runners in the remaining bottom runners 4 is repeated from step S2-2 to step S2-4.

And S4, mounting the bottom plate assembly. The main keel and the auxiliary keel of the bottom plate assembly are arranged at the bottom end of the suspension rod 6, and the height dimension of the top plate assembly 7 is adjusted after the main keel and the auxiliary keel are arranged. Then, a falling preventive bar 28 is installed between the screw 27 and the main runner.

And finally, installing a decorative bottom plate below the auxiliary keel, and coating putty and plastering on the decorative bottom plate.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a shape suspended ceiling structure of preapring for an unfavorable turn of events which characterized in that: the floor slab comprises a plurality of rows of bottom keels (4) distributed at intervals, expansion bolts (5) penetrating through the bottom keels (4) and used for being connected with a floor slab (1), hanging rods (6) connected to the expansion bolts (5), and top plate assemblies (7) connected to the hanging rods (6); end fossil fragments (4) include a plurality of sections coaxial coupling's in proper order unit fossil fragments, and unit fossil fragments include base (8) be connected with floor (1) and connect in base (8) and deviate from auxiliary positioning seat (9) of floor (1) one side, auxiliary positioning seat (9) are rotated through axis of rotation (10) relative level and are connected on base (8), expansion bolts (5) are coaxial to be worn to locate on axis of rotation (10), offer on auxiliary positioning seat (9) and be used for fixing a position auxiliary hole (33) of adjacent fossil fragments unit.

2. The ceiling structure of claim 1, which is an anti-deformation ceiling, characterized in that: the auxiliary positioning seat is characterized in that a sliding groove (24) is formed in the auxiliary positioning seat (9), the sliding groove (24) is parallel to the auxiliary positioning seat (9) in the length direction, a positioning block (23) is connected to the sliding groove (24) in a sliding mode, the auxiliary hole (33) is vertically communicated with the positioning block (23), a vertical through hole (25) is formed in the groove bottom of the sliding groove (24), and the auxiliary hole (33) vertically corresponds to the through hole (25).

3. The ceiling structure of claim 2, which is characterized in that: the lower surface of supplementary positioning seat (9) is provided with the scale that is used for showing interval size between auxiliary hole (33) axis and axis of rotation (10) axis, pointer (26) that one side fixedly connected with that locating piece (23) deviates from floor (1) radially set up along auxiliary hole (33), pointer (26) length direction's the directional auxiliary hole of one end (33) axis, the directional scale of the other end that pointer (26) is relative.

4. The ceiling structure of claim 2, which is characterized in that: the base (8) is further provided with an observation groove (13) used for aligning the transverse ink line (2) formed by lofting, the observation groove (13) is vertically arranged in a penetrating mode, and when the axis of the base (8) is parallel to the axis of the auxiliary positioning seat (9), the observation groove (13) is vertically communicated with the extending hole (25).

5. The ceiling structure of claim 4, which is characterized in that: the two ends of the observation groove (13) parallel to the length direction of the base (8) are fixedly connected with aligning plates (14) used for attaching ink lines, and the aligning plates (14) are vertically arranged.

6. The ceiling structure of claim 1, which is an anti-deformation ceiling, characterized in that: the base is characterized in that a convex block (11) is fixedly connected to one axial end of the base (8), a groove (12) is formed in the other axial end of the base (8), and the convex block (11) and the groove (12) of two adjacent bases (8) on the same bottom keel (4) are in plug-in fit.

7. The ceiling structure of claim 1, which is an anti-deformation ceiling, characterized in that: the base (8) is provided with two limiting grooves (16), the two limiting grooves (16) are arranged at intervals along the length direction of the base (8), and the two limiting grooves (16) are respectively positioned on two sides of the rotating shaft (10); when the auxiliary positioning seat (9) positions the keel unit on the adjacent bottom keel (4), the limiting part can be detachably connected in the limiting groove (16), the limiting part comprises a limiting insertion plate (18) with one end extending into the limiting groove (16), and two opposite sides of the limiting insertion plate (18) are respectively abutted against two sides of the auxiliary positioning seat (9).

8. The ceiling structure of claim 1, which is an anti-deformation ceiling, characterized in that: an additional hole (15) which is vertically communicated is formed in the base (8), a screw rod (27) penetrates through the additional hole (15), and one end of the screw rod (27) extends into the floor slab (1) and is fixed with the floor slab (1); when the auxiliary positioning seat (9) is positioned, the axis of the auxiliary positioning seat (9) is parallel to the axis of the base (8), and one end of the screw rod (27) departing from the floor slab (1) vertically penetrates through the auxiliary hole (33) of the positioning block (23).

9. The ceiling structure of claim 8, wherein: and an anti-falling rod (28) is arranged between the screw rod (27) and the main keel of the top plate component (7).

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