CN109215481B - Three-dimensional model preparation mould for architectural design - Google Patents

Abstract

A three-dimensional model manufacturing die for building design relates to a three-dimensional model die, wherein an iron sheet plate (22) is arranged on the lower surface of a model frame (1), a plurality of clamping blocks (5) are arranged on the outer side surface of an adhesive tape (6) at intervals, clamping grooves (10) between double inner folding edge plates (7) arranged on the inner side surface of a positioning block (9) are clamped on the clamping blocks of the adhesive tape, a magnet (13) is embedded in the positioning block, the adhesive tape is bent into a designed shape on a template (3) on the upper surface of the model frame, the magnet on the adhesive tape positioning block adsorbs the iron sheet plate on the lower part of the model frame to shape the adhesive tape, and a cavity (4) with a designed shape is formed in the adhesive tape; the invention puts out a pattern on the model frame according to the design through the adhesive tape and the positioning block, the positioning block obtains a stable cavity structure under the adsorption action of the magnet and the iron sheet plate, and the three-dimensional manual model is obtained after the soil is placed in the cavity for shaping, thereby facilitating the cognition of students in teaching.

Description

Three-dimensional model preparation mould for architectural design

[ technical field ] A method for producing a semiconductor device

The invention relates to a model die, in particular to a three-dimensional model manufacturing die for architectural design.

[ background of the invention ]

The building structure is a support body which forms a building and provides a space environment for use functions, and bears various loads generated under the actions of gravity, wind power, impact, vibration and the like of the building; meanwhile, the method is also a basic factor influencing the building structure, the building economy and the integral shape of the building; for buildings, roofs, walls, floor layers and the like are main components forming the using space of the buildings, and the roofs, the walls, the floor layers and the like are not only load-bearing members of the buildings, but also envelope members of the buildings; as is known, when students are taught by big, middle and primary schools, more buildings are involved, and particularly, ancient buildings and European buildings in China have unique shapes and structures; at present, teachers can only explain building structures for students through graphs on textbooks during teaching, problems of intuition and comprehension are brought to students with weak spatial sense, and especially, students cannot conduct sensory understanding on problems of space division and combination, appearance modeling and the like of building design under the condition of lack of cognition or participation.

[ summary of the invention ]

In order to overcome the defects in the background art, the invention discloses a three-dimensional model manufacturing mold for building design, wherein a figure is placed on a model frame through an adhesive tape and a positioning block according to the design, the positioning block obtains a stable cavity structure under the adsorption action of a magnet and an iron sheet plate, and a three-dimensional manual model is obtained after a soil mesh is placed in a cavity for shaping, so that the three-dimensional model is convenient for students in teaching to learn.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a three-dimensional model preparation mould for architectural design, includes model frame, iron sheet board, adhesive tape and locating piece, is equipped with the iron sheet board at model frame's lower part face, and the interval is equipped with a plurality of fixture blocks on the lateral surface of adhesive tape, and the draw-in groove card between the two inside hem boards that the locating piece medial surface set up is on the fixture block of adhesive tape, the embedding has magnet in the locating piece, bends into the design shape by the template of adhesive tape at model frame upper portion face, and at this moment the magnet on the adhesive tape locating piece adsorbs the iron sheet board of model frame lower part is stereotyped the adhesive tape, forms the die cavity of design shape in the adhesive tape.

The three-dimensional model manufacturing die for building design is characterized in that edge protrusions are respectively arranged on the periphery of the upper surface of a model frame, and a template is formed on the model frame between the edge protrusions.

The three-dimensional model manufacturing die for architectural design is characterized in that downward protruding strips are respectively arranged on the lower surfaces of two sides of a model frame, inward protruding strips are respectively arranged on the opposite surfaces of the lower ends of the downward protruding strips on the lower surfaces of the two sides of the model frame, sliding grooves are formed between the two inward protruding strips and the lower surface of the model frame, and barrier strips are arranged between the rear ends of the two inward protruding strips of the model frame.

The three-dimensional model for architectural design makes the mould, the iron sheet is through gluing or hot melt and the upper portion face fixed connection of picture peg.

The three-dimensional model manufacturing die for architectural design is characterized in that the two sides of the inserting plate, which are close to the upper part surface, are respectively provided with a protruding strip.

The three-dimensional model for architectural design makes the mould, the lower part face of picture peg is close to the front portion and is equipped with the convenient concave pit that takes out.

The three-dimensional model manufacturing die for architectural design is characterized in that a plurality of connecting blocks are arranged on the outer side surface of each adhesive tape at intervals, the outer end of each connecting block is provided with a widened clamping block, an anti-falling piece is arranged between the lower end of each clamping block and the adhesive tape, and the lower end of a double-inner-folding-edge plate arranged on one side surface of each positioning block is pressed on the anti-falling piece.

The three-dimensional model manufacturing die for building design is characterized in that a vertical plate is arranged on the inner side face of the positioning block, and the double inner folding plates are arranged on the inner side face of the vertical plate.

The three-dimensional model manufacturing die for building design is characterized in that a blind hole is formed in the lower end face of the positioning block, and the magnet is fixed in the blind hole.

The three-dimensional model manufacturing die for building design is characterized in that glass cement is coated in the blind hole of the positioning block, and the magnet is fixed in the blind hole through the bonding of the glass cement.

Due to the adoption of the technical scheme, the invention has the following beneficial effects:

when the three-dimensional model manufacturing die for building design is used, special-shaped patterns such as the strip, the block, the plate or the plate body edge with the recess, the protrusion and the like are placed on a model frame according to design through the adhesive tape and the positioning block, the positioning block obtains a stable cavity structure under the adsorption action of the magnet and the iron sheet, and a three-dimensional (D) manual model is obtained after the release agent is coated in the cavity and the added nodular soil is shaped, so that the three-dimensional model manufacturing die is convenient for students in teaching to learn; the invention can realize three-dimensional and visual building models in teaching, and can also manufacture building models such as bridges and the like according to the structure of the invention, thereby facilitating the observation and participation of students.

[ description of the drawings ]

FIG. 1 is a schematic view of the present invention in use;

FIG. 2 is a schematic perspective view of a positioning block of the present invention;

FIG. 3 is a schematic view of the position of the magnet in the positioning block of the present invention;

FIG. 4 is a perspective view of the adhesive strip of the present invention;

FIG. 5 is a schematic perspective view of a mold frame according to the present invention;

FIG. 6 is a schematic perspective view of the assembled structure of the mold frame and the insert plate of the present invention;

in the figure: 1. a model frame; 2. the edge part is raised; 3. a template; 4. a cavity; 5. a clamping block; 6. an adhesive tape; 7. double inner hem plates; 8. a vertical plate; 9. positioning blocks; 10. a card slot; 11. blind holes; 12. glass cement; 13. a magnet; 14. connecting blocks; 15. an anti-drop sheet; 16. a chute; 17. an inwardly projecting strip; 18. blocking strips; 19. a dimple; 20. a raised strip; 21. inserting plates; 22. and (4) iron sheet plates.

[ detailed description ] embodiments

The present invention will be explained in more detail by the following examples, which are intended to disclose all changes and modifications within the scope of the present invention, and the present invention is not limited to the following examples;

the three-dimensional model manufacturing die for building design shown in the attached drawings 1-6 comprises a model frame 1, iron sheet plates 22, adhesive tapes 6 and positioning blocks 9, wherein edge protrusions 2 are respectively arranged on the periphery of the upper surface of the model frame 1, a template 3 is formed on the model frame 1 between the edge protrusions 2, and the thickness of the template 3 is preferably about two millimeters; the lower part face of the model frame 1 is provided with an iron sheet plate 22, a plurality of clamping blocks 5 are arranged on the outer side face of the rubber strip 6 at intervals, clamping grooves 10 between double inner folding plates 7 arranged on the inner side face of a positioning block 9 are clamped on the clamping blocks 5 of the rubber strip 6, magnets 13 are embedded in the positioning block 9, the template 3 on the upper part face of the model frame 1 of the rubber strip 6 is bent into a designed shape, at the moment, the magnets 13 on the positioning block 9 of the rubber strip 6 adsorb the iron sheet plate 22 on the lower part of the model frame 1 to shape the rubber strip 6, and a cavity 4 in the designed shape is formed in the rubber strip 6.

With reference to the structure of the insert plate 21 and the model frame 1 shown in fig. 5 or 6, downward protruding strips are respectively arranged on the lower surfaces of both sides of the model frame 1, inward protruding strips 17 are respectively arranged on the opposite surfaces of the lower ends of the downward protruding strips on the lower surfaces of both sides of the model frame 1, a sliding groove 16 is formed between the two inward protruding strips 17 and the lower surface of the model frame 1, and a barrier strip 18 is arranged between the rear ends of the two inward protruding strips 17 of the model frame 1; the iron sheet plate 22 is fixedly connected with the upper surface of the inserting plate 21 through gluing or hot melting; the two sides of the inserting plate 21 close to the upper part surface are respectively provided with a convex strip 20; a sunken pit 19 which is convenient for taking out the inserting plate 21 is arranged on the lower surface of the inserting plate 21 close to the front part; the protruding strips 20 at two sides of the insert plate 21 on the iron sheet plate 22 are inserted into the two slide grooves 16 of the model frame 1 to form a fixed.

The structure of the positioning block 9 and the rubber strip 6 shown in the attached drawing 3 or 4 is combined, a plurality of connecting blocks 14 are arranged on the outer side surface of the rubber strip 6 at intervals, a widened clamping block 5 is arranged at the outer end of each connecting block 14, an anti-falling sheet 15 is arranged between the lower end of each clamping block 5 and the rubber strip 6, the lower end of a double-inner-folding-edge plate 7 arranged on one side surface of the positioning block 9 is pressed on the anti-falling sheet 15, and a cavity 4 formed by the rubber strip 6 is stably positioned on the model frame 1 through the positioning block 9.

With reference to the structure of the positioning block 9 shown in fig. 2 or 3, a vertical plate 8 is arranged on the inner side surface of the positioning block 9, and the double inner folding plates 7 are arranged on the inner side surface of the vertical plate 8; the lower end face of the positioning block 9 is provided with a blind hole 11, the blind hole 11 of the positioning block 9 is coated with glass cement 12, the magnet 13 is fixed in the blind hole 11 through the bonding of the glass cement 12, and the lower end face of the magnet 13 is in the same level with the lower end face of the positioning block 9.

In the three-dimensional model manufacturing die for building design, the model frame 1, the positioning block 9 and the inserting plate 21 can be made of plastic materials, and the rubber strip 6 is made of silicon rubber materials or soft plastics; when the three-dimensional model work is used, when a plate body with a notch in the middle of one side of the plate body shown in the attached drawing 1 is combined, a plurality of positioning blocks 9 are arranged outside an adhesive tape 6, then the adhesive tape 6 together with the positioning blocks 9 is placed on a template 3 of a model frame 1 to form a cavity 4 'if needed, a grid can be arranged on the template 3 so as to accurately position the cavity 4', a release agent is coated on the template 3 and the wall of the adhesive tape 6 in the cavity 4, then, the mold cavity 4 is filled with the nodular soil 'sculpture mud', after the nodular soil is dried, an inserting plate 21 is taken down to make magnets in the positioning blocks 9 lose the attraction of an iron skin plate 22, then the adhesive tape 6 and the three-dimensional model work are taken down, various shapes can be made according to needs, and then the three-dimensional model work is combined into a required building model; other configurations the present invention is not necessarily described, but any combination may be used within the scope of the present invention to obtain the model configurations not described in detail in the embodiments of the present invention.

The present invention is not described in detail in the prior art.

Claims (8)

1. The utility model provides a three-dimensional model preparation mould for architectural design, includes model frame (1), iron sheet board (22), adhesive tape (6) and locating piece (9), characterized by: an iron sheet plate (22) is arranged on the lower portion face of a model frame (1), a plurality of clamping blocks (5) are arranged on the outer side face of an adhesive tape (6) at intervals, clamping grooves (10) between double inner flanging plates (7) arranged on the inner side face of a positioning block (9) are clamped on the clamping blocks (5) of the adhesive tape (6), a magnet (13) is embedded into the positioning block (9), the adhesive tape (6) is bent into a designed shape on a template (3) on the upper portion face of the model frame (1), the magnet (13) on the positioning block (9) of the adhesive tape (6) adsorbs the iron sheet plate (22) on the lower portion of the model frame (1) to shape the adhesive tape (6), and a cavity (4) in the designed shape is formed in the adhesive tape (6); edge protrusions (2) are respectively arranged on the periphery of the upper surface of the model frame (1), a template (3) is formed on the model frame (1) between the edge protrusions (2), the template comprises an insertion plate (21), and protruding strips (20) are respectively arranged on two sides of the insertion plate (21) close to the upper surface.

2. The mold for producing a three-dimensional model for architectural design according to claim 1, wherein: downward convex strips are respectively arranged on the lower surfaces of two sides of the model frame (1), inward convex strips (17) are respectively arranged on the opposite surfaces of the lower ends of the downward convex strips on the lower surfaces of the two sides of the model frame (1), a sliding groove (16) is formed between the two inward convex strips (17) and the lower surface of the model frame (1), and a barrier strip (18) is arranged between the rear ends of the two inward convex strips (17) of the model frame (1).

3. The mold for producing a three-dimensional model for architectural design according to claim 1, wherein: the iron sheet plate (22) is fixedly connected with the upper surface of the inserting plate (21) through gluing or hot melting.

4. The mold for producing a three-dimensional model for architectural design according to claim 3, wherein: the lower surface of the inserting plate (21) is provided with a concave pit (19) which is convenient to take out near the front part.

5. The mold for producing a three-dimensional model for architectural design according to claim 1, wherein: a plurality of connecting blocks (14) are arranged on the outer side surface of the rubber strip (6) at intervals, the outer end of each connecting block (14) is provided with a widened clamping block (5), an anti-falling sheet (15) is arranged between the lower end of each clamping block (5) and the rubber strip (6), and the lower ends of double inner folding edge plates (7) arranged on one side surface of the positioning block (9) are pressed on the anti-falling sheets (15).

6. The mold for producing a three-dimensional model for architectural design according to claim 1 or 5, wherein: a vertical plate (8) is arranged on the inner side surface of the positioning block (9), and the double inner flanging plates (7) are arranged on the inner side surface of the vertical plate (8).

7. The mold for producing a three-dimensional model for architectural design according to claim 6, wherein: the lower end face of the positioning block (9) is provided with a blind hole (11), and the magnet (13) is fixed in the blind hole (11).

8. The mold for producing a three-dimensional model for architectural design according to claim 7, wherein: glass cement (12) is smeared in the blind hole (11) of the positioning block (9), and the magnet (13) is fixed in the blind hole (11) through the adhesion of the glass cement (12).

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