CN216804449U - Finished product quick drying device based on 3D prints - Google Patents

Abstract

The utility model discloses a finished product quick drying device based on 3D printing, and relates to the technical field of 3D printing. Including, the printer main part, the inside lower surface of printer main part is provided with print platform, print platform's both sides all are provided with Y axle guide rail, Z axle guide rail is installed to the top of Y axle guide rail, Y axle guide rail is sliding connection with Z axle guide rail, install X axle guide rail between the Z axle guide rail, Z axle guide rail is sliding connection with X axle guide rail, the stoving subassembly is all installed at the both ends of X axle guide rail, through installing the stoving subassembly in the printer main part, can carry out real-time stoving at the in-process of printing, realizes improving drying efficiency to printing off-the-shelf fast drying, removes damp subassembly through the installation, both can remove the tide to the raw materials, can preheat the raw materials again to reach the purpose that improves the work efficiency and the practicality of 3D printer.

Description

Finished product quick drying device based on 3D prints

Technical Field

The utility model relates to the technical field of 3D printing, in particular to a finished product quick drying device based on 3D printing.

Background

One of the rapid prototyping technologies, also called additive manufacturing, is a technology for constructing an object by printing layer by using an adhesive material such as powdered metal or plastic based on a digital model technical document, and is often used to manufacture a model in the fields of mold manufacturing, industrial design, etc., and then gradually used for direct manufacturing of some products.

Most of current 3D printing materials are because production facility is imperfect or finished product material exposes for a long time under open environment, with the moisture direct contact in the air, the 3D printing material who has inhaled too much steam can influence 3D and print off-the-shelf quality, if use, the quality of printing out will receive the influence, and current 3D printer all dries to it after printing into the finished product through with raw and other materials again, nevertheless it all has certain thickness to print the finished product, drying effect is poor, both the waste time, also be not favorable to printing material's shaping, 3D printer also can produce waste gas or even harmful gas because high temperature is processed raw and other materials at the in-process of work simultaneously, the practicality is relatively poor.

SUMMERY OF THE UTILITY MODEL

The utility model provides a finished product quick drying device based on 3D printing, and aims to solve the problems that in the prior art, the quality of a 3D printed finished product is influenced by a 3D printed material which absorbs excessive water vapor due to the fact that a production facility is imperfect or the finished product material is exposed in an open environment for a long time and is in direct contact with moisture in the air, and if the finished product material is used, the printed quality is influenced. Present 3D printer is all dried to it again after printing into the finished product through with raw and other materials, and the stoving effect is poor, both lost time, also does not benefit to the shaping of printing the material, and the 3D printer also can produce waste gas or even harmful gas because high temperature is processed raw and other materials at the in-process of work simultaneously, and the practicality is relatively poor.

In order to realize the purpose, the utility model is realized by the following technical scheme: the utility model provides a finished product quick drying device based on 3D prints, includes: the printer comprises a printer body, a printing platform is arranged on the lower surface of the interior of the printer body, Y-axis guide rails are arranged on two sides of the printing platform, a Z-axis guide rail is arranged above the Y-axis guide rail, the Y-axis guide rail and the Z-axis guide rail are in sliding connection, an X-axis guide rail is arranged between the Z-axis guide rails, the Z-axis guide rail and the X-axis guide rail are in sliding connection, drying assemblies are arranged at two ends of the X-axis guide rail, a printing nozzle is arranged on the outer surface of the X-axis guide rail in a sliding manner, a feed inlet is fixedly connected above the printing nozzle, a dehumidifying assembly is arranged above the feed inlet, a waste gas treatment assembly is arranged at the center of the upper surface of the printer body, a controller is arranged on one side of the waste gas treatment assembly, a temperature detector is arranged at the bottom of the controller and extends to the interior of the printer body, the opposite side of exhaust-gas treatment subassembly is provided with prints the raw materials, and prints the raw materials and pass in proper order and remove damp subassembly and feed inlet and be connected with the printing shower nozzle.

As the finished product quick drying device based on 3D printing, the drying assembly comprises a casing, a rectifying net, an electric heating wire, an impeller and a driving motor, one end of the casing is fixedly connected with the rectifying net, the electric heating wire is installed on the side face of the rectifying net, the impeller is installed on the other side of the electric heating wire, and the driving motor is installed in the center of the impeller.

As the finished product quick drying device based on 3D printing, the dehumidifying assembly comprises a protective shell, air outlet holes, through holes and heating wires, the air outlet holes are formed in the surface of the protective shell and distributed in an equidistant array mode, the through holes are formed in the upper end and the lower end of the protective shell, and the heating wires are installed inside the protective shell.

As the finished product quick drying device based on 3D printing, the waste gas treatment component comprises a shell, a protective net, exhaust fan blades, an exhaust motor, a ventilation plate, a moisture absorption plate and a protective cover, wherein the protective net, the exhaust fan blades, the exhaust motor, the ventilation plate and the moisture absorption plate are all arranged inside the shell, the protective net is arranged at the lower end of the shell, the exhaust fan blades are arranged on the upper side of the protective net, the exhaust motor is arranged inside the exhaust fan blades, the ventilation plate is arranged on the upper side of the exhaust fan blades, the moisture absorption plate is arranged on the upper side of the ventilation plate, and the protective cover is arranged on the upper side of the moisture absorption plate.

As the finished product quick drying device based on 3D printing, the moisture absorption plate is made of a strong-adsorbability material, the material is an activated carbon material, and the surface of the moisture absorption plate is provided with honeycomb-shaped adsorption holes.

As the finished product quick drying device based on 3D printing, the controller comprises a base, a control panel and a display, and the control panel and the display are arranged on the upper surface of the base.

The utility model provides a finished product quick drying device based on 3D printing. The method has the following beneficial effects:

this finished product quick drying device based on 3D prints, through installing the stoving subassembly in printer main part, can carry out real-time stoving at the in-process of printing, realize the quick drying to printing off-the-shelf, and the stoving unit mount is at the both ends of X axle guide rail, can realize the synchronous work of stoving subassembly and printing shower nozzle, improve drying efficiency, remove damp subassembly through the installation, both can remove the tide to the raw materials, can preheat the raw materials again, improve the finished quality of 3D printer printing and print efficiency, through installing the exhaust-gas treatment subassembly, carry out purification treatment to the waste gas that prints the in-process and produce, thereby the practicality of 3D printer has been improved.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a perspective cross-sectional view of the present invention;

FIG. 3 is an exploded view of a partial structure of the present invention;

FIG. 4 is an exploded view of a partial structure of the present invention;

FIG. 5 is a cross-sectional view of a portion of the structure of the present invention;

FIG. 6 is a partial block diagram of the present invention.

In the figure: 1. a printer main body; 2. a printing platform; 3. a Y-axis guide rail; 4. a Z-axis guide rail; 5. an X-axis guide rail; 6. a drying assembly; 601. a housing; 602. a rectifier network; 603. an electric heating wire; 604. an impeller; 605. a drive motor; 7. printing a spray head; 8. a feed inlet; 9. a moisture removal assembly; 901. a protective shell; 902. an air outlet; 903. a port; 904. heating wires; 10. an exhaust gas treatment component; 1001. a housing; 1002. a protective net; 1003. an exhaust fan blade; 1004. an exhaust motor; 1005. a breather plate; 1006. a moisture absorption plate; 1007. a protective cover; 11. a controller; 1101. a base; 1102. a control panel; 1103. a display; 12. printing raw materials; 13. a temperature detector.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments obtained by persons skilled in the art based on the embodiments in the present application without any creative work belong to the protection scope of the present application.

In the description of the present application, it is to be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present application. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; the connection can be mechanical connection or electrical connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those skilled in the art.

Referring to fig. 1-6, the present invention provides a technical solution: a finished product quick drying device based on 3D printing comprises a printer body 1, wherein a printing platform 2 is arranged on the inner lower surface of the printer body 1, Y-axis guide rails 3 are arranged on two sides of the printing platform 2, Z-axis guide rails 4 are arranged above the Y-axis guide rails 3, the Y-axis guide rails 3 are in sliding connection with the Z-axis guide rails 4, X-axis guide rails 5 are arranged between the Z-axis guide rails 4, the Z-axis guide rails 4 are in sliding connection with the X-axis guide rails 5, drying assemblies 6 are arranged at two ends of the X-axis guide rails 5, printing nozzles 7 are arranged on the outer surface of the X-axis guide rails 5 in sliding connection, a feeding port 8 is fixedly connected above the printing nozzles 7, a dehumidifying assembly 9 is arranged above the feeding port 8, a waste gas treatment assembly 10 is arranged in the center of the upper surface of the printer body 1, a controller 11 is arranged on one side of the waste gas treatment assembly 10, and a temperature detector 13 is arranged at the bottom of the controller 11, the temperature detector 13 extends to the inside of the printer main body 1, the printing raw material 12 is arranged on the other side of the waste gas treatment component 10, and the printing raw material 12 sequentially passes through the dehumidifying component 9 and the feeding hole 8 and is connected with the printing nozzle 7.

During the use, through installation stoving subassembly 6 in printer main part 1, can carry out real-time stoving at the in-process of printing, realize printing off-the-shelf fast drying, and stoving subassembly 6 installs the both ends at X axle guide rail 5, can realize stoving subassembly 6 and the synchronous working of printing shower nozzle 7, improve drying efficiency, remove damp subassembly 9 through the installation, both can remove the tide to printing raw materials 12, can preheat printing raw materials 12 again, improve the off-the-shelf quality of 3D printer printing and print efficiency.

Specifically, the drying assembly 6 includes a casing 601, a rectifying net 602, a heating wire 603, an impeller 604 and a driving motor 605, wherein one end of the casing 601 is fixedly connected with the rectifying net 602, the heating wire 603 is installed on the side surface of the rectifying net 602, the impeller 604 is installed on the other side of the heating wire 603, and the driving motor 605 is installed in the center of the impeller 604.

In the embodiment of the present invention, the heating wire 603 is installed to provide heat energy for the drying assembly 6, and meanwhile, the rectifying net 602, the impeller 604 and the driving motor 605 are installed to directionally guide the heat energy, thereby improving the drying efficiency.

Specifically, remove damp subassembly 9 and include protective housing 901, venthole 902, port 903 and heater strip 904, venthole 902 sets up on the surface of protective housing 901, and venthole 902 is the equidistance array distribution, and port 903 sets up the upper and lower both ends at protective housing 901, and heater strip 904 is installed in the inside of protective housing 901.

In the embodiment of the present invention, by installing the heating wire 904 in the dehumidifying assembly 9, before the printing material 12 enters the printing nozzle 7, the printing material 12 is heated and dehumidified in a surrounding manner, so as to accelerate the evaporation of the moisture on the surface of the printing material 12, and also to preheat the printing material 12.

Specifically, the exhaust gas treatment assembly 10 includes a housing 1001, a protective net 1002, exhaust fan blades 1003, an exhaust motor 1004, an air vent 1005, a moisture absorption plate 1006 and a protective cover 1007, wherein the protective net 1002, the exhaust fan blades 1003, the exhaust motor 1004, the air vent 1005 and the moisture absorption plate 1006 are all installed inside the housing 1001, the protective net 1002 is installed at the lower end of the housing 1001, the exhaust fan blades 1003 are installed on the protective net 1002, the exhaust motor 1004 is installed inside the exhaust fan blades 1003, the air vent 1005 is installed on the upper side of the exhaust fan blades 1003, the moisture absorption plate 1006 is installed on the upper side of the air vent 1005, and the protective cover 1007 is installed on the upper side of the moisture absorption plate 1006.

In the embodiment of the present invention, the exhaust motor 1004 drives the exhaust fan 1003 to rotate, so as to exhaust the water vapor in the printer main body 1 and the exhaust gas generated during the printing process of the printing material 12, and the water vapor and the exhaust gas are exhausted after being processed by the moisture absorption plate 1006, thereby preventing pollution.

Specifically, the moisture absorption plate 1006 is a strong-adsorbability material, which is an activated carbon material, and the surface of the moisture absorption plate 1006 is provided with honeycomb-shaped adsorption holes.

In the specific embodiment of the utility model, the activated carbon has a developed pore structure, a larger specific surface area and abundant surface chemical groups, has strong adsorption capacity and can effectively treat water vapor and waste gas.

Specifically, the controller 11 includes a base 1101, a control panel 1102, and a display 1103, and the control panel 1102 and the display 1103 are mounted on an upper surface of the base 1101.

In an embodiment of the present invention, the controller 11 may operate the drying module 6, the dehumidifying module 9 and the exhaust gas treating module 10 to meet different temperature requirements.

The working principle is as follows: in use, the printing stock 12 is first fed into the printing head 7 through the moisture removal assembly 9 and the feed inlet 8, the heating wire 904 in the moisture removal assembly 9 is wrapped around the surface of the printing stock 12, the moisture on the surface of the printing raw material 12 is fully heated and dehumidified, the printing raw material 12 is preheated, then the printing spray head 7 dries the printed model in real time by the drying component 6 in the process of molding the printing raw material 12, meanwhile, the waste gas treatment component 10 purifies the evaporated water vapor and the waste gas generated in the printing process and discharges the purified gas, the dehumidifying component 9, the drying component 6 and the waste gas treatment component 10 can be adjusted by the controller 11 in the working process, so that the drying temperature and the dehumidifying temperature are lower than the melting point of the printing raw material 12, meanwhile, the temperature detector 13 can monitor the operation of the 3D printer in real time in temperature during the printing process.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (6)

1. The utility model provides a finished product quick drying device based on 3D prints, its characterized in that includes: printer main body (1), the inside lower surface of printer main body (1) is provided with print platform (2), the both sides of print platform (2) all are provided with Y axle guide rail (3), Z axle guide rail (4) are installed to the top of Y axle guide rail (3), Y axle guide rail (3) are sliding connection with Z axle guide rail (4), install X axle guide rail (5) between Z axle guide rail (4), Z axle guide rail (4) are sliding connection with X axle guide rail (5), stoving subassembly (6) are all installed at the both ends of X axle guide rail (5), the surface slidable mounting of X axle guide rail (5) has printing shower nozzle (7), the top fixedly connected with feed inlet (8) of printing shower nozzle (7), except that damp subassembly (9) are installed to the top of feed inlet (8), exhaust-gas treatment subassembly (10) are installed at the upper surface center of printer main body (1), controller (11) are installed to one side of exhaust-gas treatment subassembly (10), temperature detector (13) are installed to the bottom of controller (11), temperature detector (13) extend to the inside of printer main part (1), the opposite side of exhaust-gas treatment subassembly (10) is provided with prints raw materials (12), and prints raw materials (12) and pass in proper order except that damp subassembly (9) and feed inlet (8) and be connected with printing shower nozzle (7).

2. The finished product quick drying device based on 3D printing of claim 1, characterized in that: drying assembly (6) includes casing (601), rectifier network (602), heating wire (603), impeller (604) and driving motor (605), the one end and rectifier network (602) fixed connection of casing (601), the side at rectifier network (602) is installed in heating wire (603), the opposite side at heating wire (603) is installed in impeller (604), the center at impeller (604) is installed in driving motor (605).

3. The finished product quick drying device based on 3D printing of claim 1, characterized in that: the dehumidifying assembly (9) comprises a protective shell (901), air outlets (902), through holes (903) and heating wires (904), wherein the air outlets (902) are formed in the surface of the protective shell (901), the air outlets (902) are distributed in an equidistant array mode, the through holes (903) are formed in the upper end and the lower end of the protective shell (901), and the heating wires (904) are installed inside the protective shell (901).

4. The finished product quick drying device based on 3D printing of claim 1, characterized in that: the waste gas treatment assembly (10) comprises an outer shell (1001), a protective screen (1002), exhaust fan blades (1003), an exhaust motor (1004), an air vent plate (1005), a moisture absorption plate (1006) and a protective cover (1007), wherein the protective screen (1002), the exhaust fan blades (1003), the exhaust motor (1004), the air vent plate (1005) and the moisture absorption plate (1006) are all installed inside the outer shell (1001), the protective screen (1002) is installed at the lower end of the outer shell (1001), the exhaust fan blades (1003) are installed on the upper side of the protective screen (1002), the exhaust motor (1004) is installed inside the exhaust fan blades (1003), the air vent plate (1005) is installed on the upper side of the exhaust fan blades (1003), the moisture absorption plate (1006) is installed on the upper side of the air vent plate (1005), and the protective cover (1007) is installed on the upper side of the moisture absorption plate (1006).

5. Finished product fast drying device based on 3D printing according to claim 4 characterized in that: the moisture absorption plate (1006) is made of a strong-adsorbability material which is an activated carbon material, and the surface of the moisture absorption plate (1006) is provided with honeycomb-shaped adsorption holes.

6. The finished product quick drying device based on 3D printing of claim 1, characterized in that: the controller (11) comprises a base (1101), a control panel (1102) and a display (1103), wherein the control panel (1102) and the display (1103) are installed on the upper surface of the base (1101).

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