CN115156544A

CN115156544A - A green water circle device for building production of aluminite powder

Info

Publication number: CN115156544A
Application number: CN202210949852.XA
Authority: CN
Inventors: 宫绍峰
Original assignee: Binzhou Xilong Building Materials Co ltd
Current assignee: Binzhou Xilong Building Materials Co ltd
Priority date: 2022-08-09
Filing date: 2022-08-09
Publication date: 2022-10-11
Anticipated expiration: 2042-08-09
Also published as: CN115156544B

Abstract

The invention discloses a green water circulation device for producing building aluminum powder, and relates to the field of aluminum powder production; the packing machine comprises a base, wherein a material conveying cylinder is fixedly arranged at the upper end of the base, the tail end of the left side of the material conveying cylinder is connected with a filter cylinder through a movable hinge and a bolt, a discharge hole is formed in the lower end wall of the right side of the material conveying cylinder, and a packing auger blade penetrates through the output shaft inside the material conveying cylinder and is positioned inside the material conveying cylinder; the left end of the liquid inlet is communicated with a horizontally arranged return pipeline, and the return port is immersed in the water storage cylinder; shaking the material device and realizing rocking of vertical and horizontal direction to the feeding cylinder, thereby the circulating water gets into to strain the impurity that the section of thick bamboo filtered the aquatic, and the retaining section of thick bamboo of two settings is realized automatically through first retaining bobbin base part, and water in the reposition of redundant personnel is inhaled the inlet tube by the water pump, avoids the circulating water to spill over the retaining bucket and accompanies you to cross, and reaches the reuse of water, economic environmental protection.

Description

A green water circle device for building production of aluminite powder

Technical Field

The invention relates to the field of aluminum powder production, in particular to a green water circulating device for producing building aluminum powder.

Background

The working principle of the hydraulic atomization method for manufacturing the aluminum powder is that after water with high pressure is atomized, the atomized water is sprayed out through symmetrically arranged nozzles and directly acts on the heated and melted aluminum liquid, and the aluminum liquid is cooled and scattered into fine aluminum powder at the intersection point of the nozzles;

among the water pressure atomizing device among the prior art, by processed aluminite powder and steam fall into the device bottom, steam can cool off the back liquefaction for liquid, and the device is dry in carrying drying device with the mixture of water and aluminite powder afterwards, and the water resource can be wasted.

Disclosure of Invention

In order to overcome the technical problems of the aluminum powder feeding device in the prior art, the invention provides a green water circulating device for producing building aluminum powder.

The invention solves the technical problem by adopting the technical scheme that the green water circulating device for producing the building aluminum powder comprises a base; the automatic feeding device is characterized in that rollers are mounted below the base, the rollers are movably mounted on sliding rails below the rollers, a feeding cylinder is fixedly mounted at the upper end of the base, a filter cylinder is connected to the left end of the feeding cylinder through a movable hinge and a bolt, the feeding cylinder and the filter cylinder are coaxial, the central axis of the feeding cylinder forms an inclination angle with the ground, the left lower side of the feeding cylinder is connected with the base through the movable hinge, a discharge port is formed in the lower end wall of the right side of the feeding cylinder in a communicated mode, a first motor is mounted at the end of the right side of the feeding cylinder and fixedly connected with an output shaft penetrating through the inside of the feeding cylinder, an auger blade penetrates through the side wall of the output shaft and is located inside the feeding cylinder, a plurality of water conveying holes are formed in the auger blade, and the diameter of each water conveying hole is smaller than the diameter of aluminum powder particles; the front side wall of the material conveying cylinder is fixedly connected with a connecting plate, a material shaking device is arranged below the connecting plate, and the lower part of the connecting plate can be abutted to the base;

the upper side wall of the left side of the material conveying cylinder is communicated with an atomizing cylinder through a first hose, the upper end of the atomizing cylinder is communicated with a feeding drip, high-pressure water nozzles are installed on two sides of the feeding drip, the high-pressure water nozzles are symmetrically installed, the left end of each high-pressure water nozzle is communicated with a vertically arranged liquid inlet, the left end of each liquid inlet is communicated with a horizontally arranged return pipeline, a water pump is installed at the upper end of each return pipeline, the high-pressure water nozzles and the feeding drip are common devices in the prior art, the water pump is a commonly used industrial liquid pump in the prior art, the left end of each return pipeline is communicated with a vertically downward return port, the return port is immersed into the first water storage cylinder, the first water storage cylinder is arranged at the lower part of the filter cylinder, the first water storage cylinder is communicated with the filter cylinder through a second hose, the first hose and the second hose are common steel wire hoses in the prior art, when the material conveying cylinder shakes, the atomizing cylinder is always in a fixed state, the material conveying cylinder is hinged to swing under the external force, and the included angle of 60 degrees between the axis of the inner part of the material conveying cylinder and the ground;

first water storage cylinder passes through connecting pipe intercommunication left side second water storage cylinder, the supporting shoe is installed to first water storage cylinder bottom, the piston dog is installed to the supporting shoe top and just being located the connection top, piston dog below butt has the piston head, the piston head both sides are connected in the waterproofing membrane upper end, and the waterproofing membrane lower extreme is installed in the supporting shoe, the piston rod is installed to the piston head below, the piston rod runs through in the supporting shoe, it has the second spring to run through on the piston rod, the second spring upper end is connected in the piston head lower extreme wall, the second spring lower extreme is connected in the supporting shoe lower extreme wall, and when water pressure was too big, the piston head was pushed down, and the second spring is pushed down to the piston head, and rivers flow into the second water storage cylinder through the connecting pipe behind the waterproofing membrane to realize from the reposition of redundant personnel, guarantee that first water storage cylinder can not take place the condition that the circulating water spills over.

Two side walls of the atomizing cylinder are fixedly connected with supporting frames; the rear of the filter cylinder is communicated with a pipe wall, the pipe wall is symmetrically provided with a water ball check block, the water ball check block is connected with a first spring, and the tail end of the first spring is connected with a water blocking ball, so that water flow cannot flow back from the lower part to enter the filter cylinder, the support frames are welded on two sides of the atomizing cylinder, and the bottom of each support frame is fixed on the ground.

The material shaking device comprises a vertical top plate, a horizontal top plate, a cam, a connecting shaft, a main bevel gear, an auxiliary bevel gear, a sheave mechanism, a supporting shaft and a second motor;

when shaking materials in the vertical direction, a vertical top plate is vertically and fixedly arranged on the lower end wall of a connecting plate, a first cam is arranged at the lower end of the vertical top plate, the right end of the first cam is arranged on the left side wall of a supporting frame through a supporting shaft, the first cam is fixedly arranged on the right side wall of a first sheave mechanism, an auxiliary bevel gear is arranged on the right side of the first sheave mechanism, the first sheave mechanism and the auxiliary bevel gear are penetrated through by a connecting shaft, the right end wall of the connecting shaft is arranged on the left side wall of the supporting frame, the auxiliary bevel gear drives the first cam to rotate to generate stroke change in the vertical direction, and the vertical top plate pushes the connecting plate to swing up and down;

when shaking materials horizontally, a horizontal top plate is horizontally and fixedly installed on the right end wall of the machine base, a second cam is installed at the right end of the horizontal top plate, the lower end of the second cam is installed on the upper end wall of the sliding rail through a supporting shaft, the second cam is fixedly installed on the lower side wall of a second sheave mechanism, an auxiliary bevel gear is installed on the upper side of the second sheave mechanism, the second sheave mechanism and the auxiliary bevel gear are penetrated through by a connecting shaft, a second motor is connected to the lower end wall of the connecting shaft, the auxiliary bevel gear is installed in a meshed mode with a main bevel gear, the main bevel gear drives the second cam to rotate to generate stroke change in the horizontal direction, the horizontal top plate pushes the machine base, a machine base driving roller slides left and right on the sliding rail, the auger blade is driven by the first motor to stir, aluminum powder is conveyed to the discharge port to drop, cooled water drops on the aluminum powder to flow into the water delivery hole through collision between the auger blade and the aluminum powder, and the material shaking device can shake the delivery cylinder to drop the water drops.

The first sheave mechanism and the second sheave mechanism respectively comprise a sheave, a drive plate and a round pin, the drive plate is arranged above the sheave, and the round pin is arranged on the drive plate; the grooved wheel of the first grooved wheel mechanism is fixedly connected to the lower side of the main bevel gear through a connecting shaft, and the grooved wheel of the second grooved wheel mechanism is fixedly connected to the left side of the auxiliary bevel gear through the connecting shaft; the round pin on the driving plate of the first geneva mechanism is arranged in the geneva wheel, the round pin on the driving plate of the first geneva mechanism is arranged outside the geneva wheel, the first geneva mechanism enters a poking state during working, the second geneva mechanism enters an intermittent state, and the stroke angles of the two geneva mechanisms are arranged in a 90-degree staggered manner in one plane.

The invention has the beneficial effects that: through shaking the setting of material device, shake the inside auger of material device and carry the aluminite powder to the discharge gate, under cam mechanism and geneva mechanism's effect, refrigerated drop of water is rocked and is separated with the aluminite powder, sink through the water delivery hole, strain a section of thick bamboo and flow into water storage cylinder through the second hose at the process, water in the water storage cylinder can be taken back return line used repeatedly after filtering, set up first water storage cylinder and second water storage cylinder, set up the supporting shoe bottom first water storage cylinder, the piston dog, the piston head, water-proof membrane, the piston rod, the automatic reposition of redundant personnel of circulating water is guaranteed to the second spring, the condition that the circulating water spilled over can not take place, the waste of water resource has been avoided.

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 only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view (cross-sectional view) of the present invention;

FIG. 2 is a schematic structural diagram of the shaking device of the present invention;

the drawing shows that 1, a base, 2, a material delivery cylinder, 3 a movable hinge, 4, a bolt, 5, a filter cylinder, 6, a discharge port, 7, a first motor, 8, an output shaft, 9, a screw blade, 10, an atomizing cylinder, 11, a feeding drip opening, 12, a high-pressure water nozzle, 13, a liquid inlet, 14, a return pipeline, 15, a water pump, 16, a return opening, 17, a first water storage cylinder, 18, a first hose, 19, a second hose, 20, a support frame, 21, a connecting plate, 22, a vertical top plate, 23, a horizontal top plate, 24, a first cam, 25 and a connecting shaft, 26, a main bevel gear, 27, a secondary bevel gear, 28, a second motor, 29, a water delivery hole, 30, a first geneva gear, 31, a support shaft, 32, a water ball stop, 33, a first spring, 34, a water blocking ball, 35, a second water storage cylinder, 36, a connecting pipe, 37, a support block, 38, a piston stop, 39, a piston head, 40, a waterproof diaphragm, 41, a piston rod, 42, a second spring, 43, a roller, 44, a shaking device, 45, a sliding rail, 46, a second cam, 47, a second geneva gear, 48, a geneva, 49, a driving plate and 50, and a round pin.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-2, the technical scheme adopted by the invention for solving the technical problems is that the green water circulation device for producing the aluminum powder for the building comprises a base 1; the aluminum powder conveying device is characterized in that a roller 43 is installed below the base 1, the roller 43 is movably mounted on a sliding rail 45 below the roller 43, a conveying cylinder 2 is fixedly installed at the upper end of the base 1, the tail end of the left side of the conveying cylinder 2 is connected with a filter cylinder 5 through a movable hinge 3 and a bolt 4, the conveying cylinder 2 and the filter cylinder 5 are coaxial, the central axis of the conveying cylinder 2 forms an inclination angle with the ground, the left lower side of the conveying cylinder 2 is connected with the base 1 through the movable hinge 3, a discharge hole 6 is formed in the lower end wall of the right side of the conveying cylinder 2 in a communicated manner, a first motor 7 is installed at the tail end of the right side of the conveying cylinder 2, the first motor 7 is fixedly connected with an output shaft 8 penetrating through the inside of the conveying cylinder 2, auger blades 9 are installed on the side wall of the output shaft 8 and positioned inside the conveying cylinder 2 in a penetrating manner, a plurality of water conveying holes 29 are formed in the auger blades 9, and the diameter of the water conveying holes 29 is smaller than the diameter of aluminum powder particles; a connecting plate 21 is fixedly connected to the front side wall of the material conveying cylinder 2, a material shaking device 22 is installed below the connecting plate 21, and the lower part of the connecting plate 21 can be abutted to the base 1;

the upper side wall of the left side of the material conveying cylinder 2 is communicated with an atomizing cylinder 10 through a first hose 18, the upper end of the atomizing cylinder 10 is communicated with a feeding drip opening 11, high-pressure water nozzles 12 are mounted on two sides of the feeding drip opening 11, the high-pressure water nozzles 12 are symmetrically mounted, the left end of each high-pressure water nozzle 12 is communicated with a vertically arranged liquid inlet 13, the left end of each liquid inlet 13 is communicated with a horizontally arranged return pipe 14, a water pump 15 is mounted at the upper end of each return pipe 14, the left end of each return pipe 14 is communicated with a vertically downward return opening 16, each return opening 16 is immersed into a first water storage cylinder 17, each first water storage cylinder 17 is arranged at the lower part of the filter cylinder 5, and each first water storage cylinder 17 is communicated with the filter cylinder 5 through a second hose 19;

the first water storage cylinder 17 is communicated with the second water storage cylinder 35 on the left through a connecting pipe 36, a supporting block 37 is mounted at the bottom of the first water storage cylinder 17, a piston block 38 is mounted above the supporting block 37 and above the connecting pipe 36, a piston head 39 is abutted against the lower side of the piston block 38, two sides of the piston head 39 are connected to the upper end of a waterproof membrane 40, the lower end of the waterproof membrane 40 is mounted in the supporting block 37, a piston rod 41 is mounted below the piston head 39, the piston rod 41 penetrates through the supporting block 37, a second spring 42 penetrates through the piston rod 41, the upper end of the second spring 42 is connected to the lower end wall of the piston head 39, the lower end of the second spring 42 is connected to the lower end wall of the supporting block 37, when the water pressure is too high, the piston head 39 is pressed downwards, the second spring 42 is pressed downwards by the piston head 39, water flows into the second water storage cylinder 35 through the connecting pipe 36 after passing through the waterproof membrane 40, so that self-diversion is realized, and the situation that the circulating water cannot overflow of the first water storage cylinder 17 occurs.

Two side walls of the atomizing cylinder 10 are fixedly connected with support frames 20; the rear part of the filter cartridge 5 is communicated with a water ball stopper 32, the wall of the water ball stopper 32 is symmetrically provided with the water ball stopper, the water ball stopper 32 is connected with a first spring 33, and the tail end of the first spring 33 is connected with a water blocking ball 34, so that water flow is prevented from flowing back to the filter cartridge 5 from the lower part.

The material shaking device 44 comprises a vertical top plate 22, a horizontal top plate 23, a cam 24, a connecting shaft 25, a main bevel gear 26, a secondary bevel gear 27, a first sheave mechanism 30, a second sheave mechanism 47, a supporting shaft 31 and a second motor 28;

when shaking materials in the vertical direction, a vertical top plate 22 is vertically and fixedly installed on the lower end wall of a connecting plate 21, a first cam 24 is installed at the lower end of the vertical top plate 22, the right end of the first cam 24 is installed on the left side wall of a supporting frame 20 through a supporting shaft 31, the first cam 24 is fixedly installed on the right side wall of a first sheave mechanism 30, an auxiliary bevel gear 27 is installed on the right side of the first sheave mechanism 30, the first sheave mechanism 30 and the auxiliary bevel gear 27 are penetrated through by a connecting shaft 25, the right end wall of the connecting shaft 25 is installed on the left side wall of the supporting frame 20, the auxiliary bevel gear 27 drives the first cam 24 to rotate to generate stroke change in the vertical direction, and the vertical top plate 22 pushes the connecting plate 21 to swing up and down;

when material shaking is carried out horizontally, the horizontal top plate 23 is horizontally and fixedly installed on the right end wall of the machine base 21, the second cam 46 is installed at the right end of the horizontal top plate 23, the lower end of the second cam 46 is installed on the upper end wall of the sliding rail 45 through the supporting shaft 31, the second cam 46 is fixedly installed on the right lower side wall of the second sheave mechanism 47, the auxiliary bevel gear 27 is installed on the upper side of the second sheave mechanism 47, the second sheave mechanism 47 and the auxiliary bevel gear 27 are penetrated through by the connecting shaft 25, the lower end wall of the connecting shaft 25 is connected with the second motor 28, the auxiliary bevel gear 27 is installed in a meshed mode with the main bevel gear 26, the main bevel gear 47 drives the second cam 46 to rotate to generate stroke change in the horizontal direction, the horizontal top plate 23 pushes the machine base 1, the machine base 1 and the driving roller 43 to slide left and right on the sliding rail 45;

the first sheave mechanism 30 and the second sheave mechanism 47 each comprise a sheave 48, a drive plate 49 and a round pin 50, the drive plate 49 is arranged above the sheave 48, and the round pin 50 is mounted on the drive plate 49; the sheave 48 of the first sheave mechanism 30 is fixedly connected to the lower side of the primary bevel gear 26 through the connecting shaft 25, and the sheave 48 of the second sheave mechanism 47 is fixedly connected to the left side of the secondary bevel gear 26 through the connecting shaft 25; the round pin 50 on the drive plate 49 of the first sheave mechanism 30 is arranged in the sheave 48, the round pin 50 on the drive plate 49 of the first sheave mechanism 30 is arranged outside the sheave 48, and when the first sheave mechanism 30 enters a toggle state and the second sheave mechanism 47 enters an intermittent state during working, so that aluminum powder to be filtered horizontally shakes after shaking up and down.

The working principle of the invention is as follows: molten metal aluminum liquid flows in from a feeding drip opening 6, then high-pressure steam sprayed by a high-pressure water nozzle 12 cools the flowing metal aluminum liquid, the cooled metal aluminum liquid forms aluminum powder at the intersection point of the high-pressure water nozzle 12, the aluminum powder falls into an auger blade 9, the auger blade 9 conveys the aluminum powder to a discharge opening 6 under the action of a first motor 7, the cooled water vapor slides down to a filter cylinder 5 along a feed delivery cylinder 2 for filtering, the filtered liquid flows into a water storage cylinder 17, part of the aluminum powder can be remained in the filter cylinder 5, and then a water pump 15 conveys circulating water in the water storage cylinder 17 again to the high-pressure water nozzle 12 through a return pipeline 14; the material shaking device is driven by a second motor 28 to drive the main bevel gear 26 and the auxiliary bevel gear 27, and then drives the first sheave mechanism 30 and the second sheave mechanism 47 to rotate, so that the material conveying cylinder 2 can shake in the horizontal and vertical directions; when the water pressure is too high, the piston head 39 is pressed down, the piston head 39 presses down the second spring 42, and water flows into the second water storage cylinder 35 through the connecting pipe 36 after passing through the waterproof diaphragm 40, so that self-shunting is realized, and the condition that circulating water overflows cannot happen to the first water storage cylinder 17.

Of course, the above description is not limited to the above examples, and the undescribed technical features of the present invention can be implemented by or using the prior art, and will not be described herein again; the above embodiments and drawings are only for illustrating the technical solutions of the present invention and not for limiting the present invention, and the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that changes, modifications, additions or substitutions within the spirit and scope of the present invention may be made by those skilled in the art without departing from the spirit of the present invention, and shall also fall within the scope of the claims of the present invention.

Claims

1. A green water circulation device for producing aluminum powder for buildings comprises a base (1); the aluminum powder conveying device is characterized in that rollers (43) are installed below the base (1), the rollers (43) are movably arranged on sliding rails (45) below the rollers (43), a conveying cylinder (2) is fixedly installed at the upper end of the base (1), the left end of the conveying cylinder (2) is connected with a filter cylinder (5) through a movable hinge (3) and a bolt (4), the conveying cylinder (2) and the filter cylinder (5) are coaxial, the central axis of the conveying cylinder (2) forms an inclination angle with the ground, the left lower side of the conveying cylinder (2) is connected with a machine base (1) through the movable hinge (3), the lower end wall of the right side of the conveying cylinder (2) is provided with a discharge port (6), a first motor (7) is installed at the tail end of the right side of the conveying cylinder (2), the first motor (7) is fixedly connected with an output shaft (8) penetrating through the inside of the conveying cylinder (2), auger blades (9) are arranged on the side wall of the output shaft (8) and are located inside of the conveying cylinder (2) in a penetrating mode, a plurality of auger blades (9) are arranged, and the diameter of the auger blades (29) is smaller than that of aluminum powder conveying particles; a connecting plate (21) is fixedly connected to the front side wall of the material conveying cylinder (2), a material shaking device (22) is installed below the connecting plate (21), and the lower part of the connecting plate (21) can abut against the base (1); the left upper side wall of the material conveying cylinder (2) is communicated with an atomizing cylinder (10) through a first hose (18), the upper end of the atomizing cylinder (10) is communicated with a feeding drip opening (11), high-pressure water nozzles (12) are installed on two sides of the feeding drip opening (11), the high-pressure water nozzles (12) are symmetrically installed, the left end of the high-pressure water nozzle (12) is communicated with a vertically-arranged liquid inlet (13), the left end of the liquid inlet (13) is communicated with a horizontally-arranged backflow pipeline (14), a water pump (15) is installed at the upper end of the backflow pipeline (14), the left end of the backflow pipeline (14) is communicated with a vertically downward backflow opening (16), the backflow opening (16) is immersed into a first water storage cylinder (17), the first water storage cylinder (17) is arranged at the lower part of the filter cylinder (5), and the first water storage cylinder (17) is communicated with the filter cylinder (5) through a second hose (19); first water storage cylinder (17) pass through connecting pipe (36) intercommunication left side second water storage cylinder (35), supporting shoe (37) are installed to first water storage cylinder (17) bottom, supporting shoe (37) top just is located connecting pipe (36) top and installs piston dog (38), piston dog (38) below butt has piston head (39), piston head (39) both sides are connected in waterproofing membrane (40) upper end, and the lower extreme of waterproofing membrane (40) is installed in supporting shoe (37), piston rod (41) are installed to piston head (39) below, piston rod (41) run through in supporting shoe (37), it has second spring (42) to run through on piston rod (41), second spring (42) upper end is connected in piston head (39) lower end wall, second spring (42) lower extreme is connected in supporting shoe (37) lower end wall.

2. The green water circulation device for aluminum powder production in buildings according to claim 1 is characterized in that two side walls of the atomizing cylinder (10) are fixedly connected with supporting frames (20); the rear of the filter cylinder (5) is communicated with a water ball stopper (32) symmetrically installed on the wall of the filter cylinder, the water ball stopper (32) is connected with a first spring (33), and the tail end of the first spring (33) is connected with a water blocking ball (34).

3. The green water circulation device for building aluminum powder production as claimed in claim 1, wherein the shaking device (44) comprises a vertical top plate (22), a horizontal top plate (23), a cam (24), a connecting shaft (25), a main bevel gear (26), a secondary bevel gear (27), a first sheave mechanism (30), a second sheave mechanism (47), a supporting shaft (31) and a second motor (28); the vertical top plate (22) is vertically and fixedly mounted on the lower end wall of the connecting plate (21), a first cam (24) is mounted at the lower end of the vertical top plate (22), the right end of the first cam (24) is mounted on the left side wall of the supporting frame (20) through a supporting shaft (31), the first cam (24) is fixedly mounted on the right side wall of the first sheave mechanism (30), an auxiliary bevel gear (27) is mounted on the right side of the first sheave mechanism (30), the first sheave mechanism (30) and the auxiliary bevel gear (27) are penetrated through by a connecting shaft (25), and the right end wall of the connecting shaft (25) is mounted on the left side wall of the supporting frame (20); horizontal roof (23) horizontal fixed mounting is in frame (21) right side end wall, second cam (46) are installed to horizontal roof (23) right-hand member, second cam (46) lower extreme is installed in slide rail (45) upper end wall through back shaft (31), second cam (46) fixed mounting is lateral wall under second sheave mechanism (47) right side, and vice bevel gear (27) are installed to second sheave mechanism (47) upside, and second sheave mechanism (47) and vice bevel gear (27) are run through by connecting axle (25), it is connected with second motor (28) to connect axle (25) lower extreme wall, vice bevel gear (27) and main bevel gear (26) meshing installation.

4. The green water circulation device for building aluminum powder production as claimed in claim 1, wherein the first sheave mechanism (30) and the second sheave mechanism (47) each comprise a sheave (48), a dial (49) and a round pin (50), the dial (49) is arranged above the sheave (48), and the round pin (50) is mounted on the dial (49); the grooved wheel (48) of the first grooved wheel mechanism (30) is fixedly connected to the lower side of the main bevel gear (26) through the connecting shaft (25), and the grooved wheel (48) of the second grooved wheel mechanism (47) is fixedly connected to the left side of the auxiliary bevel gear (26) through the connecting shaft (25); the round pin (50) on the drive plate (49) of the first geneva mechanism (30) is arranged in the geneva gear (48), and the round pin (50) on the drive plate (49) of the first geneva mechanism (30) is arranged outside the geneva gear (48).