CN219085579U - Beam design splicing model for stop log type framework - Google Patents

Abstract

The utility model belongs to the technical field of building simulation, and particularly relates to a beam design splicing model for a stop beam type framework, which comprises a base, eave columns and gold columns, wherein threaded holes are symmetrically formed on the surface of the base, threaded seats are uniformly formed at the bottoms of the eave columns and the gold columns, and the bottoms of the eave columns and the gold columns are connected with the threaded holes through the threaded seats in a threaded manner; the eave column is lower than the gold column, a first inserting hole is formed in the eave column and the surface of the gold column in a penetrating mode, a supporting purlin is inserted into the inner cavity of the first inserting hole, two groups of the gold column tops are movably connected with five beams, connecting seats are symmetrically arranged at two ends of the upper surface of the five beams, three beams are connected between the two groups of the connecting seats, the supporting purlin comprises a head holding purlin and an inserting purlin, and the head holding purlin is located above the inserting purlin; the novel installation is simple, and the installation stability is high, can piece together the simulation to kind of roof beam formula for the framework crossbeam design.

Description

Beam design splicing model for stop log type framework

Technical Field

The utility model relates to the technical field of building simulation, in particular to a beam design splicing model for a stop log type framework.

Background

The beam is supported on the upright post and lifted again. The application range is wide, and the wood frame building is widely used in large-scale buildings such as palace, temple and the like, and is more selected by a Royal building group, and is a representative of wood frame buildings.

The existing beam design splicing model for the stop log framework is of an integral structure generally, and can not be used for rapidly splicing each structural part according to design requirements, so that the beam design is inconvenient to simulate, and the beam design splicing model for the stop log framework is provided for solving the problems.

Disclosure of Invention

Object of the utility model

In order to solve the technical problems in the background art, the utility model provides a beam design splicing model for a stop-beam type framework, which is simple to install and high in installation stability, and can carry out splicing simulation on the beam design for the stop-beam type framework.

(II) technical scheme

In order to solve the technical problems, the utility model provides a crossbeam design splicing model for a stop beam type framework, which comprises a base, eave columns and gold columns, wherein threaded holes are symmetrically formed on the surface of the base, threaded seats are uniformly formed at the bottom parts of the eave columns and the gold columns, and the eave columns and the bottom parts of the gold columns are connected with the threaded holes through the threaded seats in a threaded manner;

the eave column is lower than the gold column in height, a first plug hole is formed in the eave column and the surface of the gold column in a penetrating mode, a supporting square column is inserted into the inner cavity of the first plug hole, two groups of the eave column are movably connected with five beams at the top of the gold column, connecting seats are symmetrically arranged at two ends of the upper surface of the five beams, and three beams are connected between the two groups of the connecting seats.

Preferably, the supporting purlin comprises a holding purlin and a penetrating purlin, and the holding purlin is located above the penetrating purlin.

Preferably, the two ends and the middle part of the three frame beams, the two ends of the five frame beams and the top of the eave column are all provided with arc grooves.

Preferably, the middle part of the three-frame beam is provided with a ridge purlin through an arc groove, and the two ends of the three-frame beam, the two ends of the five-frame beam and the top of the eave column are all provided with gold purlins.

Preferably, the middle parts of the connecting seat, the eave column, the gold column and the three beams are all penetrated and provided with second plug holes, and the inner cavities of the second plug holes are penetrated and plugged with purlin columns.

Preferably, the bottoms of the two ends of the gold purlin and the ridge purlin are uniformly and integrally formed with plug-in columns, the tops of the inner cavities of the arc-shaped grooves are provided with plug-in grooves, and the plug-in grooves are matched with the plug-in columns.

Preferably, the cornice rafter is arranged above the gold purlin and the purlin column, the cornice rafter is of a herringbone structure, and the cornice rafter end part is integrally formed with the fly rafter.

The technical scheme of the utility model has the following beneficial technical effects:

1. according to the utility model, the arc grooves are formed at the two ends and the middle part of the three-frame beam, the two ends of the five-frame beam and the top of the eave column, the golden purlin and the ridge purlin can be limited through the arc grooves, the two ends of the lower surfaces of the golden purlin and the ridge purlin are integrally formed with the inserting columns, the inner cavities of the arc grooves are provided with the inserting grooves, the inserting columns and the inserting grooves are mutually inserted, so that the stability of the installation of the golden purlin and the ridge purlin can be improved, the installation is simple, the installation stability is high, and the splicing simulation can be performed on the beam design for the stacked beam type framework.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic diagram of an exploded construction of the present utility model;

FIG. 3 is a schematic view of a girder erection joint structure of the present utility model;

FIG. 4 is a schematic diagram of a connecting structure of a eave pillar and a gold pillar according to the present utility model.

Reference numerals:

1. a base; 2. a threaded hole; 3. eave column; 4. gold column; 5. a screw seat; 6. a first plug hole; 7. supporting purlin; 8. five beams; 9. a connecting seat; 10. three beams; 11. an arc-shaped groove; 12. gold purlin; 13. a ridge purlin; 14. a second plug hole; 15. column purlin; 16. a plug-in column; 17. cornice rafters; 18. and (5) flying rafters.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.

As shown in fig. 1-4, the beam design splicing model for the stop beam type framework provided by the utility model comprises a base 1, eave columns 3 and gold columns 4, wherein threaded holes 2 are symmetrically formed in the surface of the base 1, threaded seats 5 are integrally formed at the bottoms of the eave columns 3 and the gold columns 4, and the bottoms of the eave columns 3 and the gold columns 4 are in threaded connection with the threaded holes 2 through the threaded seats 5;

the height of the eave column 3 is lower than that of the gold column 4, a first inserting hole 6 is formed in the eave column 3 and the surface of the gold column 4 in a penetrating mode, a supporting purlin 7 is inserted into the inner cavity of the first inserting hole 6, two groups of the eave column 4 are movably connected with five beams 8 at the top of the gold column, connecting seats 9 are symmetrically arranged at two ends of the upper surface of the five beams 8, and three beams 10 are connected between the two groups of the connecting seats 9.

It should be noted that, the two ends of the holding head purlin and the inserting purlin are respectively connected with the first inserting holes 6 on the eave column 3 and the gold column 4 in an inserting way, the eave column 3 and the gold column 4 can be assembled rapidly, the bottoms of the eave column 3 and the gold column 4 are connected with the screw threads of the screw holes 2 arranged on the surface of the base 1 through the screw thread seat 5, the two ends of the five-frame beam 8 are respectively connected with the top of the gold column 4 in an inserting way, and meanwhile, the two ends of the three-frame beam 10 are respectively inserted into the connecting seats 9 at the two ends of the upper surface of the five-frame beam 8, so that the three-frame beam 10 can be fixed through the connecting seats 9.

In this embodiment, as shown in fig. 2-4, the supporting beam 7 includes a holding beam and a penetrating beam, and the holding beam is located above the penetrating beam.

It should be noted that, through holding the first purlin and inserting purlin to eave column 3 and gold column 4, both promoted the joint strength between eave column 3 and the gold column 4, simulated true stopbeam structure again.

In this embodiment, as shown in fig. 4, the two ends and the middle part of the three-frame beam 10, the two ends of the five-frame beam 8 and the top of the eave column 3 are all provided with arc grooves 11.

It should be noted that, the arc-shaped groove 11 can play a limiting role in assembling the purlin 12 and the ridge purlin 13, and improve the installation accuracy of the purlin 12 and the ridge purlin 13.

In this embodiment, as shown in fig. 2, a ridge purlin 13 is disposed in the middle of the three-frame beam 10 through an arc-shaped groove 11, and gold purlins 12 are disposed at two ends of the three-frame beam 10, two ends of the five-frame beam 8 and the top of the eave column 3.

The purlin 12 may support the rafters 17.

In this embodiment, as shown in fig. 2 and fig. 3, the middle parts of the connection seat 9, the eave column 3, the gold column 4 and the three beams 10 are all provided with a second plugging hole 14 in a penetrating manner, and the inner cavity of the second plugging hole 14 is provided with a balk column 15 in a penetrating manner.

In this embodiment, as shown in fig. 3, the bottoms of the two ends of the purlin 12 and the ridge purlin 13 are uniformly formed with plug-in posts 16, the top of the inner cavity of the arc-shaped groove 11 is provided with plug-in grooves, and the plug-in grooves are matched with the plug-in posts 16.

It should be noted that, the stability of the installation of the purlin 12 and the ridge purlin 13 can be improved by mutually plugging the plugging posts 16 and the plugging grooves.

In this embodiment, as shown in fig. 1 and 3, a cornice 17 is disposed above the purlin 12 and the purlin post 15, the cornice 17 has a herringbone structure, and a fly rafter 18 is integrally formed at an end of the cornice 17.

The purlin posts 15, the purlin 12 and the ridge purlin 13 are covered by the cornice 17 and the fly rafters 18, and the roof can be covered.

The working principle and the using flow of the utility model are as follows: the utility model provides a square column is embraced with alternate purlin both ends and is pegged graft with a jack 6 on the eaves post 3 and the gold column 4 respectively and link to each other, can carry out quick equipment to eaves post 3 and gold column 4, and the screw hole 2 screw thread that the eaves post 3 and gold column 4 bottom were offered through screw seat 5 and base 1 surface links to each other, five frame roof beams 8 both ends are pegged graft respectively with gold column 4 top and are linked to each other, three frame roof beams 10 both ends are pegged graft respectively in fifth frame roof beams 8 upper surface connecting seat 9 simultaneously, thereby accessible connecting seat 9 fixes three frame roof beams 10, three frame roof beams 10 both ends and middle part, five frame roof beams 8 both ends and eaves post 3 top all offer arc recess 11, can carry out spacingly to gold purlin 12 and ridge post 13 through arc recess 11, and gold purlin 12 and the equal body shaping in 13 lower surface both ends have spliced pole 16, and the arc recess 11 inner chamber has all been offered the spliced groove, and spliced pole 16 and spliced mutually can promote the stability of installing gold 12 and ridge purlin 13, connecting seat 9, three frame roof beams 3, three frame roof beams 10 and three frame roof beams 10 are equipped with two-shaped roof beams 15, can be directly put forward and peg graft the hole 15 in two-shaped roof beams 15, the design is realized in two-shaped roof beams 15, two-shaped roof beams 15 are mutually, two roof beams are 11 are mutually matched, and 15 are mutually and can be directly pegged graft in the face of the roof beams, and 15 is 11, the roof beams are 11, and 15 is 15.

It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.

Claims (7)

1. The beam design splicing model for the stop log type framework is characterized by comprising a base (1), eave columns (3) and gold columns (4), wherein threaded holes (2) are symmetrically formed in the surface of the base (1), threaded seats (5) are integrally formed in the bottoms of the eave columns (3) and the gold columns (4), and the bottoms of the eave columns (3) and the gold columns (4) are connected with the threaded holes (2) through the threaded seats (5) in a threaded mode;

the utility model discloses a gold frame bridge is characterized by comprising a gold frame column (4), a support purlin (7), a connecting seat (9), a connecting seat (10) and a connecting seat (9), wherein the height of the eave column (3) is lower than that of the gold frame column (4), the eave column (3) and the surface of the gold frame column (4) are all penetrated and provided with a first plug hole (6), the inner cavity of the first plug hole (6) is plugged with the support purlin (7), two groups of the gold frame column (4) is movably connected with the five frame beams (8) at the top, the two ends of the upper surface of the five frame beams (8) are symmetrically provided with the connecting seat (9), and the three frame beams (10) are connected between the connecting seat (9).

2. The beam design and assembly model for a stop-beam type framework according to claim 1, wherein the supporting beam (7) comprises a head-holding beam and a penetrating beam, and the head-holding beam is located above the penetrating beam.

3. The beam design splicing model for the stop log type framework according to claim 2, wherein arc-shaped grooves (11) are formed in two ends and the middle of the three-frame beam (10), two ends of the five-frame beam (8) and the top of the eave column (3).

4. The beam design splicing model for the stop log framework according to claim 1, wherein a ridge purlin (13) is arranged in the middle of the three-frame beam (10) through an arc-shaped groove (11), and gold purlins (12) are arranged at two ends of the three-frame beam (10), two ends of the five-frame beam (8) and the top of the eave column (3).

5. The beam design splicing model for the stop log framework of claim 4, wherein two plug holes (14) are formed in the middle of each of the connecting seat (9), the eave column (3), the gold column (4) and the three beams (10), and two column (15) are formed in the inner cavity of each of the two plug holes (14) in a penetrating and inserting mode.

6. The beam design splicing model for the stop log framework of claim 5, wherein splicing columns (16) are uniformly and integrally formed at the bottoms of two ends of the purlin (12) and the ridge purlin (13), splicing grooves are formed at the tops of inner cavities of the arc-shaped grooves (11), and the splicing grooves are matched with the splicing columns (16).

7. The beam design splicing model for a stop log framework according to claim 4, wherein a cornice (17) is arranged above the golden purlin (12) and the purlin column (15), the cornice (17) is of a herringbone structure, and a fly rafter (18) is integrally formed at the end part of the cornice (17).

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