CN211882534U - Make three-dimensional printing device of shoes - Google Patents

Abstract

The utility model discloses a make three-dimensional printing device of shoes, including base and printing room, inside exhaust-gas treatment mechanism and the stoving dehumidification mechanism of being provided with of base, and exhaust-gas treatment mechanism right side is provided with the stoving dehumidification mechanism, and the base front side is fixed with the control box simultaneously, the printing room is linked together through first gas-supply pipe and exhaust-gas treatment mechanism, the stoving dehumidification mechanism left and right sides is linked together with the drying chamber through third gas-supply pipe and second gas-supply pipe respectively, and all is provided with first exhaust fan in second gas-supply pipe and the first gas-supply pipe, is provided with the force (forcing) pump on the third gas-supply pipe simultaneously, the inside top of drying chamber is fixed with the gas-distributing pipe, all run through the conveyer belt in printing room and the drying chamber. This make shoes three-dimensional printing device is provided with exhaust-gas treatment mechanism, and the two-layer filter screen in the exhaust-gas treatment mechanism carries out primary treatment to harmful gas, and the gas after the processing gets into in the active carbon case, and the active carbon package in the active carbon case is handled waste gas once more.

Description

Make three-dimensional printing device of shoes

Technical Field

The utility model relates to a shoemaking technical field specifically is a shoemaking three-dimensional printing device.

Background

Shoes have a long history of development. Approximately 5000 years ago in the yangshao culture period, the most primitive shoe made of hide appeared. Shoes are a tool for protecting feet of people from being injured. At first, in order to overcome special conditions and prevent feet from being difficult or injured, fur shoes are invented.

The existing three-dimensional printing device for shoe making can generate gas harmful to human body when in use, harmful gas enters into the body and harms the health of the body, printed matters need to be dried after printing, and hot gas after being used during drying is not recycled, so that resource waste is caused.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a three-dimensional printing device of shoemaking to current shoemaking three-dimensional printing device who proposes in solving above-mentioned background art can produce the gas harmful to the human body when using, gets into internal harm healthy if harmful gas, needs to carry out drying process to the printed matter after the printing, and steam after using does not retrieve it when drying and recycles, causes the problem of wasting of resources.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a make three-dimensional printing device of shoes, includes base and printing room, inside exhaust-gas treatment mechanism and the stoving dehumidification mechanism of being provided with of base, and exhaust-gas treatment mechanism right side is provided with the stoving dehumidification mechanism, and the base front side is fixed with the control box simultaneously, the printing room is linked together through first gas-supply pipe and exhaust-gas treatment mechanism, the stoving dehumidification mechanism left and right sides is linked together with the drying chamber through third gas-supply pipe and second gas-supply pipe respectively, and all is provided with first exhaust fan in second gas-supply pipe and the first gas-supply pipe, is provided with the force (forcing) pump on the third gas-supply pipe simultaneously, the inside top of drying chamber is fixed with the gas-distributing pipe, and the gas-distributing pipe downside runs through there is the shower nozzle, and the gas-distributing pipe is linked together with the third gas-supply pipe simultaneously, all run through in printing room and the.

Preferably, exhaust-gas treatment mechanism includes exhaust-gas treatment ware shell, filter screen, activated carbon box, air inlet, sealed lid and second exhaust fan, exhaust-gas treatment ware shell sliding connection has the filter screen, and the filter screen right side is provided with the activated carbon box, and exhaust-gas treatment ware shell upside runs through simultaneously has sealed lid, activated carbon box runs through in the left side has the air inlet, and activated carbon box right side runs through has the second exhaust fan, and activated carbon incasement portion has placed the activated carbon package simultaneously.

Preferably, the filter screen is provided with two layers, and the grid density of the filter screen on the left side is greater than that of the filter screen on the right side.

Preferably, the printing chamber right side is provided with driving motor, and the driving motor output rotates and is connected with the screw rod, and the screw rod downside is provided with 3D printing module simultaneously.

Preferably, the number of the gas distribution pipes is two, and nine spray heads penetrate through the lower sides of the two gas distribution pipes at equal distances.

Preferably, stoving dehumidification mechanism includes heating cabinet, heater, temperature sensor, fourth blast pipe, dehumidifier and drain pipe, the inside base of heating cabinet is fixed with the heater, and temperature sensor on the inner wall of heating cabinet left side, and the heater is provided with two simultaneously, and two heater symmetries set up, the heating cabinet right side is linked together through fourth blast pipe and dehumidifier, and the dehumidifier downside runs through there is the drain pipe.

Compared with the prior art, the beneficial effects of the utility model are that: the three-dimensional printing device for the shoe-making,

(1) be provided with exhaust-gas treatment mechanism, the two-layer filter screen in the exhaust-gas treatment mechanism carries out primary treatment to harmful gas, and in the gas entering activated carbon box after the processing, the activated carbon package in the activated carbon box handled waste gas once more, and the gaseous exhaust-gas treatment mechanism of discharging at last after the processing reduces harmful gas and gets into human inside, guarantees that personnel are healthy.

(2) Be provided with stoving dehumidification mechanism, the dehumidifier among the stoving dehumidification mechanism carries out dehumidification processing to retrieving steam, and steam after the dehumidification processing gets into and continues to heat in the heating cabinet, because of retrieving steam from taking the temperature, can practice thrift heating time like this to play the effect of practicing thrift the electric energy source, and the heater is provided with two, can shorten whole heat time, improves drying efficiency.

Drawings

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

FIG. 2 is a schematic view of the distribution structure of the waste gas treatment mechanism in the base of the present invention;

FIG. 3 is a left side view of the structure of the present invention;

fig. 4 is a rear view structure diagram of the present invention;

fig. 5 is the schematic diagram of the work flow structure of the control box of the present invention.

In the figure: 1. the base, 2, exhaust-gas treatment mechanism, 3, stoving dehumidification mechanism, 4, first gas-supply pipe, 5, the printing room, 6, the second gas-supply pipe, 7, the drying chamber, 8, first exhaust-gas fan, 9, the third gas-supply pipe, 10, the force (forcing) pump, 11, the gas-distributing pipe, 12, the shower nozzle, 13, driving motor, 14, the screw rod, 15, 3D printing module, 16, the board is placed to the vamp, 17, the exhaust-gas treater shell, 18, the filter screen, 19, the active carbon case, 20, the air inlet, 21, sealed lid, 22, the second exhaust fan, 23, the heating cabinet, 24, the heater, 25, temperature sensor, 26, fourth blast pipe, 27, the dehumidifier, 28, the drain pipe, 29, the conveyer belt, 30, the control box.

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a three-dimensional printing device for shoemaking is disclosed, as shown in figure 1, figure 2, figure 4 and figure 5, a waste gas treatment mechanism 2 and a drying and dehumidifying mechanism 3 are arranged in a base 1, the drying and dehumidifying mechanism 3 is arranged on the right side of the waste gas treatment mechanism 2, a control box 30 is fixed on the front side of the base 1, the control box 30 is electrically connected with a first exhaust fan 8, a pressure pump 10, a driving motor 13, a 3D printing module 15, a second exhaust fan 22, a heater 24, a temperature sensor 25, a dehumidifier 27 and a conveyor belt 29, the waste gas treatment mechanism 2 comprises a waste gas processor shell 17, a filter screen 18, an activated carbon box 19, an air inlet 20, a sealing cover 21 and a second exhaust fan 22, the waste gas processor shell 17 is connected with the filter screen 18 in a sliding manner, the activated carbon box 19 is arranged on the right side of the filter screen 18, the sealing cover 21 is penetrated on the upper side of the waste gas processor shell, and the right side of the activated carbon box 19 is penetrated with a second exhaust fan 22, meanwhile, an activated carbon bag is placed in the activated carbon box 19, the filter screens 18 are provided with two layers, the grid density of the filter screen 18 at the left side is greater than that of the filter screen 18 at the right side, the arrangement of the two layers of filter screens 18 can carry out primary treatment on harmful gas generated during printing, large-particle impurities in waste gas are adsorbed, the gas for treatment enters the activated carbon box 19 under the action of the second exhaust fan 22, the activated carbon bag in the activated carbon box 19 continuously adsorbs the harmful gas, the treated gas is discharged out of the activated carbon box 19 under the action of the second exhaust fan 22, thus, the harmful gas can be reduced to enter the printing chamber, the printing environment quality is improved, the printing chamber 5 is communicated with the waste gas treatment mechanism 2 through a first gas pipe 4, the right side of the printing chamber 5 is provided with a driving motor 13, and the output end of the driving motor 13 is rotatably connected with a, meanwhile, the 3D printing module 15 is arranged on the lower side of the screw 14, the driving motor 13 is started under the action of the control box 30, the driving motor 13 rotates to drive the screw 14 to rotate, the screw 14 rotates to drive the 3D printing module 15 to move left and right, and therefore the 3D printing module 15 can perform three-dimensional printing on the vamp on the lower side.

As shown in fig. 2 and 4, the left and right sides of the drying and dehumidifying mechanism 3 are respectively communicated with the drying chamber 7 through a third air pipe 9 and a second air pipe 6, the second air pipe 6 and the first air pipe 4 are both provided with a first exhaust fan 8, meanwhile, the third air pipe 9 is provided with a pressure pump 10, the drying and dehumidifying mechanism 3 comprises a heating box 23, a heater 24, a temperature sensor 25, a fourth exhaust pipe 26, a dehumidifier 27 and a drain pipe 28, the inner base of the heating box 23 is fixed with the heater 24, the inner wall of the left side of the heating box 23 is provided with the temperature sensor 25, the two heaters 24 are arranged at the same time, the two heaters 24 are symmetrically arranged, the right side of the heating box 23 is communicated with the dehumidifier 27 through the fourth exhaust pipe 26, the drain pipe 28 penetrates through the lower side of the dehumidifier 27, the arrangement of the two heaters 24 can accelerate the air heating speed, the heated hot air enters the third air pipe 9 under the action, hot air enters the air distributing pipe 11 through the third air conveying pipe 9, the hot air enters the spray head 12 through the air distributing pipe 11, the hot air dries the vamps in the drying chamber 7 through the spray head 12, the dried hot air enters the dehumidifier 27 for dehumidification under the action of the first exhaust fan 8 in the second air conveying pipe 6, the hot air is continuously heated through the heating box 23 after dehumidification, the used hot air can be recycled, resource waste is reduced, heating time is shortened, the whole drying efficiency is improved, the air distributing pipe 11 is fixed at the top end inside the drying chamber 7, the spray head 12 penetrates through the lower side of the air distributing pipe 11, the air distributing pipe 11 is communicated with the third air conveying pipe 9, the air distributing pipe 11 is provided with two air distributing pipes, nine spray heads 12 penetrate through the lower sides of the two air distributing pipes 11 at equal distances, eighteen spray heads 12 can uniformly dry the vamps inside the drying chamber 7, the drying quality is ensured, the conveying belts 29 penetrate through the printing chamber 5 and the drying chamber 7, and the vamp placing plate 16 is fixed on the conveying belts 29.

The working principle is as follows: when the shoe-making three-dimensional printing device is used, an external power supply is switched on, the type of the temperature sensor 25 is CWDZ11, vamps are pasted on the vamp placing plate 16, the conveying belt 29 is started under the action of the control box 30, the vamps enter the required position in the printing chamber 5 through the left side of the printing chamber 5 under the action of the conveying belt 29, the driving motor 13, the 3D printing module 15, the first exhaust fan 8 and the waste gas treatment mechanism 2 in the first air conveying pipe 4 are started under the action of the control box 30, the driving motor 13 rotates to drive the screw rod 14 to rotate, the screw rod 14 rotates to drive the 3D printing module 15 to reciprocate, the 3D printing module 15 moves left and right to carry out three-dimensional printing treatment on the vamps on the vamp placing plate 16, a large amount of harmful gas can be generated during three-dimensional printing of the vamps, the harmful gas is pumped into the waste gas processor shell 17 under the action of the first exhaust fan 8 in, the waste gas is firstly treated under the action of two layers of filter screens 18 in a shell 17 of the waste gas processor, the waste gas enters an activated carbon box 19 through an air inlet 20 under the action of a second exhaust fan 22 after the treatment is finished, the activated carbon bag in the activated carbon box 19 treats harmful gas again, the harmful gas is treated more thoroughly, the gas treated under the action of the second exhaust fan 22 is discharged out of the activated carbon box 19, if the filter screen 18 and the activated carbon bag need to be replaced, a sealing cover 21 is manually opened, the filter screen 18 is manually pulled, the filter screen 18 is separated from the inner wall of the shell 17 of the waste gas processor, so the filter screen 18 can be replaced, the activated carbon bag can be replaced by manually taking out the activated carbon bag from the activated carbon box 19, a conveyor belt 29 is started again under the action of a control box 30 after the three-dimensional printing of the vamp is finished, the printed vamp is moved to the inside of a drying chamber 7 from the left side by the conveyor belt 29, the pressure pump 10 is started under the action of the control box 30, the first exhaust fan 8 in the second air delivery pipe 6, the heater 24, the temperature sensor 25 and the dehumidifier 27 are started, natural wind enters the heating box 23 through the dehumidifier 27 and the fourth exhaust pipe 26 under the action of the first exhaust fan 8 in the second air delivery pipe 6, the heater 24 in the heating box 23 heats the natural wind, when the temperature in the heating box 23 reaches the standard, the temperature sensor 25 transmits information to the control box 30, the pressure pump 10 is started under the action of the control box 30, the heated air enters the third air delivery pipe 9, the hot air enters the air distribution pipe 11 through the third air delivery pipe 9, the hot air enters the spray head 12 through the air distribution pipe 11, finally, the hot air is used for drying the printed vamp through the spray head 12, the hot air used during drying enters the dehumidifier 27 through the second air delivery pipe 6 under the action of the first exhaust fan 8 in the second air delivery pipe 6, the dehumidification is performed by the dehumidifier 27, and the dehumidified hot air is introduced into the heating box 23 through the fourth exhaust pipe 26 and is further heated, so that the hot air can be recycled, and the water generated during the dehumidification of the hot air is discharged out of the dehumidifier 27 through the drain pipe 28, which is not described in detail in this specification and is known in the prior art by those skilled in the art.

The terms "central," "longitudinal," "lateral," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for ease of description, but are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the scope of the invention.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a make shoes three-dimensional printing device, includes base (1) and printing chamber (5), its characterized in that: the drying and dehumidifying device is characterized in that a waste gas treatment mechanism (2) and a drying and dehumidifying mechanism (3) are arranged in the base (1), the right side of the waste gas treatment mechanism (2) is provided with the drying and dehumidifying mechanism (3), a control box (30) is fixed on the front side of the base (1), the printing chamber (5) is communicated with the waste gas treatment mechanism (2) through a first gas pipe (4), the left side and the right side of the drying and dehumidifying mechanism (3) are respectively communicated with the drying chamber (7) through a third gas pipe (9) and a second gas pipe (6), a first exhaust fan (8) is arranged in the second gas pipe (6) and the first gas pipe (4), a pressure pump (10) is arranged on the third gas pipe (9), a gas distributing pipe (11) is fixed on the top end inside the drying chamber (7), a spray head (12) penetrates through the lower side of the gas distributing pipe (11), and the gas distributing pipe (11) is communicated with the third gas pipe (9), conveying belts (29) penetrate through the printing chamber (5) and the drying chamber (7), and vamp placing plates (16) are fixed on the conveying belts (29).

2. The stereolithography apparatus for shoemaking according to claim 1, wherein: exhaust-gas treatment mechanism (2) include exhaust-gas treatment ware shell (17), filter screen (18), activated carbon box (19), air inlet (20), sealed lid (21) and second exhaust fan (22), exhaust-gas treatment ware shell (17) sliding connection has filter screen (18), and filter screen (18) right side is provided with activated carbon box (19), and exhaust-gas treatment ware shell (17) upside runs through simultaneously has sealed lid (21), activated carbon box (19) left side runs through has air inlet (20), and activated carbon box (19) right side runs through has second exhaust fan (22), and activated carbon box (19) inside has placed the activated carbon package simultaneously.

3. The stereolithography apparatus for shoemaking according to claim 2, wherein: the filter screen (18) is provided with two layers, and the grid density of the filter screen (18) on the left side is greater than that of the filter screen (18) on the right side.

4. The stereolithography apparatus for shoemaking according to claim 1, wherein: printing chamber (5) right side is provided with driving motor (13), and driving motor (13) output rotates and is connected with screw rod (14), and screw rod (14) downside is provided with 3D printing module (15) simultaneously.

5. The stereolithography apparatus for shoemaking according to claim 1, wherein: the number of the gas distribution pipes (11) is two, and nine spray heads (12) penetrate through the lower sides of the two gas distribution pipes (11) at equal distances.

6. The stereolithography apparatus for shoemaking according to claim 1, wherein: drying and dehumidifying mechanism (3) are including heating cabinet (23), heater (24), temperature sensor (25), fourth blast pipe (26), dehumidifier (27) and drain pipe (28), the inside base of heating cabinet (23) is fixed with heater (24), and temperature sensor (25) on heating cabinet (23) left side inner wall, and heater (24) are provided with two simultaneously, and two heater (24) symmetry set up, heating cabinet (23) right side is linked together through fourth blast pipe (26) and dehumidifier (27), and dehumidifier (27) downside runs through drain pipe (28).

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