CN113829622A - BIM-based 3D printing device for printing house - Google Patents

Abstract

The invention discloses a BIM-based 3D printing device for printing houses, which comprises a 3D printer, wherein the 3D printer comprises a working platform assembly, a material storage box body and a main control platform assembly, the working platform assembly comprises a working platform and a fixing clamp assembly, a material stirring groove is formed in the material storage box body, a main rod rotating device is fixed on the upper surface of the main control platform assembly, a telescopic rod assembly is fixed at the upper end of the main rod rotating device, a sliding rod supporting assembly is fixed at the top of the telescopic rod assembly, a stabilizing frame device is arranged at one end of the sliding rod supporting assembly, a spray head is connected to the lower end of the stabilizing frame device, and an ultraviolet lamp is installed on one side of the stabilizing frame device. The method is directly based on BIM data modeling analysis and then transmitted to the 3D printer for printing, and the 3D printer is printed more truly and stably by using accurate and automatic analysis modeling of BIM data.

Description

BIM-based 3D printing device for printing house

Technical Field

The invention mainly relates to the technical field of 3D printing, in particular to a BIM-based 3D printing device for printing houses.

Background

In 2013, a 3D printed house concept is established for the first time in a London Soft kill Design building Design studio in the UK, the 3D printed house needs to be fixed by nylon buckles or buttons, and meanwhile, the traditional building technology is used. This design concept was proposed at 3D printing exhibitions, month 10 2012, and instead of using solid wall construction, it was constructed on a skeletal basis with a fiber nylon structure, named "printed house 2.0", using the same minimalist abstract process, using enough plastic to ensure structural integrity. This 3D printed house concept will be a revolutionary change in house construction and can even eventually address the british housing crisis.

The existing 3D printer technology is less in relation to a house, mostly, the house is spliced for printing out wallboard models, the stability of the house is poor, the structure is single, and people can live in the house without the sense of safety.

Therefore, there is a need to develop 3D printer technology that combines realistic building construction to accurately design and conform to building construction from the beginning of modeling, especially to directly print out a building model in one piece, resulting in a more complete casting solution and robust building data model for the construction industry.

Disclosure of Invention

The invention relates to a BIM-based 3D printing device for printing houses, which comprises a 3D printer, wherein the 3D printer comprises a working platform assembly, a material storage box body and a main control platform assembly;

the working platform assembly comprises four working platforms and four fixing clamp assemblies, the four fixing clamp assemblies are symmetrically arranged on two sides of each working platform in pairs, the fixing clamp assemblies are provided with right-angle movable rods, the lower ends of the right-angle movable rods are provided with sliding positioning assemblies, the lower ends of the sliding positioning assemblies are provided with supporting rods, the two supporting rods are symmetrically arranged at the lower end of each working platform, supporting legs are fixed at four top corners of the lower surface of each working platform one by one, and the two supporting rods are symmetrically fixed on the supporting legs;

four material stirring tanks are arranged in the material storage box body one by one, spiral stirring rods are arranged in the material stirring tanks, the rear ends of the spiral stirring rods are connected with a first driving motor one by one through a chain, the first driving motor is positioned at the rear end of the material storage box body, a material pumping and pressurizing device is arranged on one side of the first driving motor, and the material pumping and pressurizing device is connected with the rear end of the material storage box body;

the upper surface of main control platform subassembly is fixed with mobile jib rotary device, mobile jib rotary device upper end is fixed with telescopic link subassembly, telescopic link subassembly top is fixed with slide bar supporting component, slide bar supporting component keeps away from the one end of telescopic link subassembly is equipped with the steady rest device, steady rest device lower extreme is connected with the shower nozzle, just the steady rest device is kept away from ultraviolet lamp is installed to one side of slide bar supporting component.

Furthermore, a plurality of the sliding positioning components comprise positioning pins and pulleys.

Furthermore, the two support rods are provided with positioning holes and sliding grooves, and the pulleys are symmetrically arranged in the sliding grooves in pairs.

Furthermore, the main rod rotating device comprises a second driving motor and a ball bearing turntable.

Furthermore, telescopic link subassembly one side is fixed with infrared ray range unit, just infrared ray range unit ray orientation does the top of telescopic link subassembly.

Furthermore, a fixed platform is arranged at one end of the sliding rod supporting assembly, a third driving motor is fixed at the upper end of the fixed platform, a main supporting rod is fixed at the output end of the third driving motor, a sliding connecting rod is sleeved outside the main supporting rod in a surrounding manner, and a fourth driving motor and a fifth driving motor are symmetrically arranged at two ends of the sliding connecting rod.

Furthermore, the upper end face of the main support rod is provided with a strip-shaped groove, and two sides of the main support rod are provided with roller travel grooves.

Further, the inner wall upper end of the sliding connecting rod with be provided with the ball between the rectangular recess, just the inner wall bilateral symmetry of sliding connecting rod is equipped with the gyro wheel, two the gyro wheel is connected with fourth driving motor's output.

Furthermore, the fifth driving motor output end is connected with the spirochete, the spirochete upper end is equipped with the drive gear axle, the drive gear axle is kept away from the one end of spirochete is equipped with the linkage wheelset, just the linkage wheelset sets up the inside of steady rest device, the lower extreme of linkage wheelset is equipped with the movable pulley support, movable pulley support lower extreme with the shower nozzle is connected.

Furthermore, be fixed with intelligent heating device on the shower nozzle, intelligent heating device lower extreme is equipped with two micropore injector heads, and two the micropore injector head is for dismantling.

Compared with the prior art, the invention has the beneficial effects that: the method is based on the technical support of the BIM, so that the modeling process of the 3D printer is more accurate, specifically, the building model and accurate data are generated by modeling through the BIM at the computer end and are transmitted to the control end of the 3D printer to drive the 3D printer to work;

the 3D printer displayed by the invention is similar to a building tower crane device in structural design, so that the authenticity of the 3D printer during building of a house model is better displayed, the main rod rotating device is utilized to flexibly and omnidirectionally convert the direction in the printing process, then the telescopic rod component is utilized to be matched with infrared distance measurement, the 3D printer is accurately and stably lifted in the building model building process, the sliding rod is utilized to support the moving stabilizing frame device in front and back of the component, the nozzle arranged under the stabilizing frame device can also transversely move left and right through the linkage wheel set, the whole building process is realized, the 3D printer is very flexible and accurate due to the matching of all components, the nozzle at the front end is provided with a structure with double spray holes, the materials are accurately sprayed by division and cooperation, the ultraviolet lamp is utilized to quickly solidify and form the materials, the real house building is simulated, and the 3D house printing technology provides some better technical characteristics, and the model is formed in one step, complex procedures such as splicing and building are not needed, and the implementation technology with convenience, rapidness and high building quality is shown.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic flow chart of the present invention;

FIG. 2 is a schematic view of the overall construction of the present invention;

fig. 3 is a specific structural schematic diagram of the material storage box of the invention:

FIG. 4 is a schematic diagram of a specific structure of a work platform assembly according to the present invention;

FIG. 5 is a schematic view of a specific structure of the main lever rotating device of the present invention;

FIG. 6 is a schematic view of a slide bar support assembly according to the present invention;

FIG. 7 is a schematic view of the slide positioning assembly of the present invention showing the construction of parts;

FIG. 8 is an enlarged view of area A of FIG. 4 in accordance with the present invention;

FIG. 9 is a schematic view of the internal component configuration of the slide bar support assembly of the present invention;

FIG. 10 is a schematic view showing the internal structure of the stabilizer device according to the present invention;

FIG. 11 is a schematic view showing an external configuration of the head of the present invention.

Reference numerals:

the device comprises a 1-3D printer, a 11-working platform assembly, a 11 a-fixed clamp assembly, a 11 a-1-right-angle movable rod, a 11 a-2-sliding positioning assembly, a 11a-3 positioning pin, a 11 a-4-pulley, a 11 b-supporting rod, a 11 b-1-positioning hole, a 11 b-2-chute, a 111-working platform, a 111 a-supporting leg, a 12-material storage box body, a 12 a-material stirring groove, a 12 b-spiral stirring rod, a 12 c-first driving motor, a 12D-material pumping supercharging device, a 13-main control platform assembly, a 13 a-main rod rotating device, a 13 b-second driving motor, a 13 c-ball bearing rotating disc, a 14-telescopic rod assembly, a 14 a-infrared distance measuring device, 15-sliding rod supporting component, 15 a-fixed platform, 15 b-third driving motor, 15 c-main supporting rod, 15 d-sliding connecting rod, 15 f-fourth driving motor, 15 c-1-long groove, 15 c-2-ball, 15 f-1-roller travel groove, 15 f-2-roller, 16-stabilizing frame device, 16 a-fifth driving motor, 16 a-1-spiral body, 16 a-2-transmission gear shaft, 16 b-ultraviolet lamp, 16 c-linkage wheel set, 16 c-1-movable wheel support, 16 d-spray head, 16 d-1-intelligent heating device and 16 d-2-micropore spray head.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention.

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Please refer to fig. 1 to 11, which particularly relate to a printing apparatus for 3D printing house based on BIM, comprising a 3D printer 1, wherein the 3D printer 1 comprises a working platform assembly 11, a material storage box 12 and a main operating platform assembly 13.

Specifically, the working platform assembly 11 includes a working platform 111 and fixing clamp assemblies 11a, four fixing clamp assemblies 11a are provided, a plurality of fixing clamp assemblies 11a are symmetrically arranged on two sides of the working platform 111 in pairs, a plurality of fixing clamp assemblies 11a are provided with right-angle movable rods 11a-1, the lower ends of the right-angle movable rods 11a-1 are provided with sliding positioning assemblies 11a-2, the lower ends of the sliding positioning assemblies 11a-2 are provided with support rods 11b, two support rods 11b are symmetrically arranged at the lower end of the working platform 111, four top corners of the lower surface of the working platform 111 are fixed with the support legs 111a one by one, two support rods 11b are symmetrically fixed on the support legs 111a, in this embodiment, a smooth bottom plate to be used can be placed on the working platform 111, the four fixing clamp assemblies 11a are used for fixing, and when the fixing position needs to be adjusted, the position can be adjusted by using a plurality of sliding positioning assemblies 11 a-2.

Specifically, material storage box 12 is inside to be equipped with four material stirred tanks 12a one by one, and is a plurality of the inside spiral stirring rod 12b that is equipped with of material stirred tank 12a, it is a plurality of the rear end of spiral stirring rod 12b is connected with first driving motor 12c through the chain one by one, first driving motor 12c is located material storage box 12 rear end, just first driving motor 12c one side is equipped with draws material supercharging equipment 12d, draw material supercharging equipment 12d with material storage box 12 rear end is connected, in this embodiment, will print the material and prepare the back, and the classification is put into a plurality of material stirred tanks 12a, and is through a plurality of spiral stirring rod 12b stirs, prevents that liquid material from solidifying, and when not needing to use, it can to close first driving motor's switch.

Specifically, the last fixed surface of main control platform subassembly 13 has mobile jib rotary device 13a, mobile jib rotary device 13a upper end is fixed with telescopic link subassembly 14, telescopic link subassembly 14 top is fixed with slide bar supporting component 15, slide bar supporting component 15 is kept away from telescopic link subassembly 14's one end is equipped with steady rest device 16, steady rest device 16 lower extreme is connected with shower nozzle 16d, just steady rest device 16 keeps away from ultraviolet lamp 16b is installed to one side of slide bar supporting component 15, in this embodiment, equipment during operation shower nozzle 16d is through nimble part cooperation to and BIM's accurate data transmission control shower nozzle 16d carries out very accurate injection site position.

Please refer to fig. 4, fig. 7 and fig. 8 again, the sliding positioning assemblies 11a-2 include positioning pins 11a-3 and pulleys 11a-4, two of the supporting rods 11b are provided with positioning holes 11b-1 and sliding grooves 11b-2, and the pulleys 11a-4 are located in the sliding grooves 11b-2 in a pairwise symmetric manner, in this embodiment, the sliding positioning assemblies 11a-2 cooperate with the positioning pins 11a-3 and the positioning holes 11b-1 to position the proper position, thereby effectively preventing the smooth bottom plate from shifting.

Please refer to fig. 1 and 5, wherein the main rod rotating device 13a includes a second driving motor 13b and a ball bearing rotating disc 13c, an infrared distance measuring device 14a is fixed on one side of the telescopic rod assembly 14, and the direction of the ray of the infrared distance measuring device 14a is the top end of the telescopic rod assembly 14.

Please refer to fig. 1 and fig. 6, a fixed platform 15a is disposed at one end of the sliding rod supporting assembly 15, a third driving motor 15b is fixed at the upper end of the fixed platform 15a, a main supporting rod 15c is fixed at the output end of the third driving motor 15b, a sliding connecting rod 15d is sleeved outside the main supporting rod 15c, a fourth driving motor 15f and a fifth driving motor 16a are symmetrically disposed at two ends of the sliding connecting rod 15d, a long-strip groove 15c-1 is disposed on the upper end surface of the main supporting rod 15c, roller travel grooves 15f-1 are disposed on two sides of the main supporting rod 15c, a ball 15c-2 is disposed between the upper end of the inner wall of the sliding connecting rod 15d and the long-strip groove 15c-1, rollers 15f-2 are symmetrically disposed on two sides of the inner wall of the sliding connecting rod 15d, two rollers 15f-2 are connected to the output end of the fourth driving motor 15f, in this embodiment, the sliding link 15d is moved back and forth on the main support rod 15c by using a plurality of parts in cooperation.

Please refer to fig. 1, fig. 10 and fig. 11, an output end of the fifth driving motor 16a is connected with a spiral body 16a-1, an upper end of the spiral body 16a-1 is provided with a transmission gear shaft 16a-2, one end of the transmission gear shaft 16a-2 far away from the spiral body 16a-1 is provided with a linkage wheel set 16c, the linkage wheel set 16c is arranged inside the stable frame device 16, a lower end of the linkage wheel set 16c is provided with a movable wheel support 16c-1, a lower end of the movable wheel support 16c-1 is connected with the spray head 16d, the spray head 16d is fixed with an intelligent heating device 16d-1, the lower end of the intelligent heating device 16d-1 is provided with two micro-pore spray heads 16d-2, and the two micro-pore spray heads 16d-2 are detachable, in this embodiment, the movable wheel support 16c-1 drives the nozzles to move simultaneously when moving transversely, and then the intelligent heating device 16d-1 heats the material inside the nozzles, so as to effectively prevent the nozzles 16d from being blocked due to material solidification, and the two micropore injection heads 16d-2 can inject different materials.

The working principle of the invention is as follows:

the invention is based on BIM technical support, 3D printer 1 modeling process is more accurate, the 3D printer 1 displayed by the invention is similar to a building tower crane device in structural design, authenticity of the 3D printer 1 in building a house model is better displayed, direction is flexibly and omnidirectionally converted in the printing process by using a main rod rotating device 13a, then a telescopic rod component 14 is used for matching with an infrared distance measurement 14a to accurately and stably lift in the building model building process, a movable stable frame device 16 at the front and the back of a sliding rod supporting component 15 is used, a spray head 16D arranged under the stable frame device 16 can also transversely move left and right through a linkage wheel set 16c, the whole building process is realized, the 3D printer 1 is very flexible and accurate due to matching of all components, the spray head 16D at the front end has a structure with double spray holes, the components cooperate to accurately spray the material, which is rapidly solidified and shaped by the ultraviolet lamp 16b, to simulate real building construction.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides a printing device who prints house based on 3D of BIM, including 3D printer (1), its characterized in that: the 3D printer (1) comprises a working platform assembly (11), a material storage box body (12) and a main control platform assembly (13);

the working platform component (11) comprises a working platform (111) and a fixing clamp component (11a), the number of the fixing clamp assemblies (11a) is four, a plurality of the fixing clamp assemblies (11a) are arranged on two sides of the working platform (111) in a pairwise symmetry manner, the plurality of fixed clamp assemblies (11a) are provided with right-angle movable rods (11a-1), the lower ends of the right-angle movable rods (11a-1) are provided with sliding positioning assemblies (11a-2), the lower ends of the sliding positioning assemblies (11a-2) are provided with supporting rods (11b), the two supporting rods (11b) are symmetrically arranged at the lower end of the working platform (111), supporting legs (111a) are fixed on four top corners of the lower surface of the working platform (111) one by one, and the two supporting rods (11b) are symmetrically fixed on the supporting legs (111 a);

the material storage box body (12) is inside to be equipped with four material stirred tanks (12a) one by one, and is a plurality of material stirred tank (12a) is inside to be equipped with spiral stirring rod (12b), and is a plurality of the rear end of spiral stirring rod (12b) is connected with first driving motor (12c) through the chain one by one, first driving motor (12c) are located the rear end of material storage box body (12), just first driving motor (12c) one side is equipped with draws material supercharging equipment (12d), draw material supercharging equipment (12d) with the rear end of material storage box body (12) is connected.

The last fixed surface of main control platform subassembly (13) has mobile jib rotary device (13a), the upper end of mobile jib rotary device (13a) is fixed with telescopic rod subassembly (14), the top of telescopic rod subassembly (14) is fixed with slide bar supporting component (15), slide bar supporting component (15) are kept away from the one end of telescopic rod subassembly (14) is equipped with steadying frame device (16), the lower extreme of steadying frame device (16) is connected with shower nozzle (16d), just steadying frame device (16) are kept away from ultraviolet lamp (16b) are installed to one side of slide bar supporting component (15).

2. The BIM-based 3D printing device for printing house according to claim 1, wherein: the sliding positioning components (11a-2) comprise positioning pins (11a-3) and pulleys (11 a-4).

3. The BIM-based 3D printing device for printing house according to claim 1, wherein: the two support rods (11b) are provided with positioning holes (11b-1) and sliding grooves (11b-2), and the pulleys (11a-4) are symmetrically arranged in pairs in the sliding grooves (11 b-2).

4. The BIM-based 3D printing device for printing house according to claim 1, wherein: the main rod rotating device (13a) comprises a second driving motor (13b) and a ball bearing rotating disc (13 c).

5. The BIM-based 3D printing device for printing house according to claim 1, wherein: an infrared distance measuring device (14a) is fixed on one side of the telescopic rod assembly (14), and the ray direction of the infrared distance measuring device (14a) is the top end of the telescopic rod assembly (14).

6. The BIM-based 3D printing device for printing house according to claim 1, wherein: one end of the sliding rod supporting assembly (15) is provided with a fixed platform (15a), the upper end of the fixed platform (15a) is fixed with a third driving motor (15b), the output end of the third driving motor (15b) is fixed with a main supporting rod (15c), the outer part of the main supporting rod (15c) is sleeved with a sliding connecting rod (15d), and the two ends of the sliding connecting rod (15d) are symmetrically provided with a fourth driving motor (15f) and a fifth driving motor (16 a).

7. The BIM-based 3D printing device for printing house according to claim 6, wherein: the upper end face of the main support rod (15c) is provided with a strip-shaped groove (15c-1), and two sides of the main support rod (15c) are provided with roller travel grooves (15 f-1).

8. The BIM-based 3D printing apparatus for printing house according to claim 7, wherein: the upper end of the inner wall of the sliding connecting rod (15d) and the ball (15c-2) are arranged between the long-strip grooves (15c-1), rollers (15f-2) are symmetrically arranged on two sides of the inner wall of the sliding connecting rod (15d), and the two rollers (15f-2) are connected with the output end of a fourth driving motor (15 f).

9. The BIM-based 3D printing device for printing house according to claim 1, wherein: the output of fifth driving motor (16a) is connected with spirochete (16a-1), the upper end of spirochete (16a-1) is equipped with drive gear axle (16a-2), drive gear axle (16a-2) are kept away from the one end of spirochete (16a-1) is equipped with linkage wheelset (16c), just linkage wheelset (16c) set up the inside of steady rest device (16), the lower extreme of linkage wheelset (16c) is equipped with loose wheel support (16c-1), the lower extreme of loose wheel support (16c-1) with shower nozzle (16d) are connected.

10. The BIM-based 3D printing apparatus for printing house according to claim 9, wherein: be fixed with intelligent heating device (16d-1) on shower nozzle (16d), the lower extreme of intelligent heating device (16d-1) is equipped with two micropore shower heads (16d-2), and two micropore shower head (16d-2) are for dismantling.

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