CN219003640U - Magnesium aluminum alloy granule preparation facilities - Google Patents

Magnesium aluminum alloy granule preparation facilities Download PDF

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CN219003640U
CN219003640U CN202222923424.8U CN202222923424U CN219003640U CN 219003640 U CN219003640 U CN 219003640U CN 202222923424 U CN202222923424 U CN 202222923424U CN 219003640 U CN219003640 U CN 219003640U
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sieve
group
plates
box
discharging
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张旭光
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    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
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Abstract

The utility model relates to the technical field of material processing, in particular to a magnesium-aluminum alloy particle preparation device. Including the box, the inside of box has set gradually first sieve group, second sieve group, third sieve group from last to down, and first sieve group, second sieve group, third sieve group are the slope setting, and the outside of box and with first sieve group, second sieve group, the lower position department of one end of third sieve group are provided with first reposition of redundant personnel discharging case, second reposition of redundant personnel discharging case, third reposition of redundant personnel discharging case respectively. According to the utility model, through the structural design of the first sieve plate group, the second sieve plate group and the third sieve plate group, the device can carry out multiple screening on materials, so that the device can screen out more materials for classification, the processing of raw materials on firework and firecracker products with more specifications is facilitated, and the screened classification can be classified and discharged through the structural cooperation of the first diversion discharging box, the second diversion discharging box and the third diversion discharging box.

Description

Magnesium aluminum alloy granule preparation facilities
Technical Field
The utility model relates to the technical field of material processing, in particular to a magnesium-aluminum alloy particle preparation device.
Background
Magnesium ingot and aluminum ingot are smelted to form magnesium aluminum alloy blocks, magnesium aluminum alloy particles are crushed into particles and are packed, and the particles with the meshes are sieved out by a sieve; the magnesium-aluminum alloy particles and the coarse alloy are mainly used for firework small products, morning glory products, firework firecracker products and the like.
The patent describes that "the screening operation in the prior art needs to be used in a screening machine, the existing screening machine generally comprises a vibrating machine, a screening box and a plurality of layers of filter plates arranged in the screening box, alloy particles with different particle diameters can pass through the filter plates through vibration of the vibrating machine, then the alloy particles with different particle diameters are respectively remained on the different filter plates", and the technical defects that a producer is inconvenient to take out the alloy particles on the different filter plates from the screening box, the material taking process is long in delay time and screening efficiency is restricted "are proposed.
In summary, the following technical problems exist in the prior art: production personnel are inconvenient to take out alloy particles on the different filter plates from the screening box, and the material taking process is long in delay time and limits screening efficiency, so that the application provides a magnesium aluminum alloy particle preparation device, and a novel technical scheme is provided for solving the technical problem mentioned in the above patent.
Disclosure of Invention
The utility model aims to provide a magnesium aluminum alloy particle preparation device, which aims at the technical problems: production personnel are inconvenient to take out alloy particles on different filter plates from a screening box, and the material taking process is long in delay time, so that the screening efficiency is restricted.
In order to solve the technical problems, the utility model adopts the following technical scheme:
the utility model provides a magnalium granule preparation facilities, includes the box, the inside of box has set gradually first sieve group, second sieve group, third sieve group from top to bottom, first sieve group, second sieve group, third sieve group are the slope setting, the outside of box and with first sieve group, second sieve group, third sieve group lower one end position department be provided with first reposition of redundant personnel discharging case, second reposition of redundant personnel discharging case, third reposition of redundant personnel discharging case respectively;
the outside of box just is located the position department of the higher one end of first sieve group, second sieve group, third sieve group and has all been seted up the installing port, the outside of installing port is provided with the baffle, the lower extreme and the box of baffle rotate to be connected, the upper end of baffle is connected with the box through the buckle.
Preferably, the first screen plate group is set to be high on the left and low on the right, the second screen plate group is set to be high on the left and low on the right, and the third screen plate group is set to be high on the left and low on the right.
Preferably, the first screen plate group comprises an upper screen plate, a middle screen plate and a lower screen plate, the upper screen plate is positioned at the upper end position of the middle screen plate, the lower screen plate is positioned at the lower end position of the middle screen plate, an upper discharging channel, a middle discharging channel and a lower discharging channel are respectively arranged in the first diversion discharging box, the upper discharging channel is communicated with the upper surface of the upper screen plate, the middle discharging channel is communicated with the upper surface of the middle screen plate, and the lower discharging channel is communicated with the upper surface of the lower screen plate; the lower end position of the lower sieve plate is also provided with a guide plate with the same inclination direction as the lower sieve plate, and one lower end of the guide plate is provided with an opening.
Preferably, the second sieve plate group comprises two upper sieve plates and two lower sieve plates, the two upper sieve plates are located at the upper end positions of the two lower sieve plates, two upper discharging channels and two lower discharging channels are respectively formed in the second separating and discharging box, the two upper discharging channels are communicated with the upper surfaces of the two upper sieve plates, the two lower discharging channels are communicated with the upper surfaces of the two lower sieve plates, two guide plates with the same inclination direction as the two lower sieve plates are further arranged at the lower ends of the two lower sieve plates, and an opening is formed in one lower end of each guide plate.
Preferably, the third sieve group comprises three upper sieve plates, three lower sieve plates and three guide plates, the three upper sieve plates are located at the upper end positions of the three lower sieve plates, the three guide plates are located at the lower end positions of the three lower sieve plates, the three guide plates with the same inclination direction as the three lower sieve plates are further arranged at the lower end positions of the three lower sieve plates, three upper discharging channels, three discharging channels and three lower discharging channels are respectively arranged in the third diversion discharging box, the three upper discharging channels are communicated with the upper surface of the three upper sieve plates, the three discharging channels are communicated with the upper surface of the three lower sieve plates, and the three lower discharging channels are communicated with the upper surface of the three guide plates.
Preferably, a throwing port is arranged at the top end of the box body.
Preferably, the buckle is in sliding connection with the box body, the buckle seat is fixed on the upper portion of the baffle, and the buckle is in buckling connection with the buckle seat.
It can be clearly seen that the technical problems to be solved by the present application must be solved by the above-mentioned technical solutions of the present application.
Through the technical scheme, the utility model has at least the following beneficial effects:
through the structural design of first sieve group, second sieve group, third sieve group for the device can carry out multiple screening to the material, makes the device screen out more classification with the material, is convenient for carry out the processing of raw materials to the fireworks and crackers goods of more specifications, and through the structure cooperation of first reposition of redundant personnel discharging case, second reposition of redundant personnel discharging case, third reposition of redundant personnel discharging case, can carry out categorised ejection of compact to the classification of screening out for the device carries out the ejection of compact when sustainable processing, has improved the efficiency of processing.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.
FIG. 1 is a front view of the whole structure of a magnesium aluminum alloy particle preparation device;
FIG. 2 is a schematic view of a first screen plate set of a magnesium aluminum alloy particle production apparatus;
FIG. 3 is a schematic view of a second screen plate set of a magnesium aluminum alloy particle production apparatus;
FIG. 4 is a schematic structural view of a third screen plate set of a magnesium aluminum alloy particle production apparatus;
FIG. 5 is a schematic diagram of a screen plate mounting structure of a magnesium aluminum alloy particle production apparatus;
fig. 6 is a connection structure diagram of the screen plate installation of the magnesium aluminum alloy particle preparation device.
In the figure: 1. a case; 2. a delivery port; 3. a first screen panel set; 4. a second screen panel set; 5. a third screen panel set; 6. a first split discharge box; 7. a second tap off bin; 8. a third split discharge box; 9. an upper screen plate; 10. a middle sieve plate; 11. a lower sieve plate; 12. a deflector; 13. an upper discharge channel; 14. a middle discharging channel; 15. a lower discharge channel; 16. a second upper sieve plate; 17. a second lower sieve plate; 18. two guide plates; 19. a second upper discharge channel; 20. a second discharging channel; 21. thirdly, a screen plate is arranged; 22. a third lower sieve plate; 23. three guide plates; 24. a third upper discharge channel; 25. three discharging channels; 26. a third discharging channel; 27. a mounting port; 28. a baffle; 29. a buckle; 30. a buckle seat; 31. and a sliding groove.
Detailed Description
The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.
Referring to fig. 1-6, a magnesium-aluminum alloy particle preparation device comprises a box body 1, wherein a delivery opening 2 is formed in the top end of the box body 1 for conveniently delivering materials, a first sieve plate group 3, a second sieve plate group 4 and a third sieve plate group 5 are sequentially arranged in the box body 1 from top to bottom, the first sieve plate group 3, the second sieve plate group 4 and the third sieve plate group 5 are all obliquely arranged, wherein the first sieve plate group 3 is arranged to be high left and low right, the second sieve plate group 4 is arranged to be high left and low right, the third sieve plate group 5 is arranged to be high left and low right, and a first diversion discharging box 6, a second diversion discharging box 7 and a third diversion discharging box 8 are respectively arranged at the positions of the lower ends of the first sieve plate group 3, the second sieve plate group 4 and the third sieve plate group 5 in the box body 1; the materials are screened for multiple times through the first sieve plate group 3, the second sieve plate group 4 and the third sieve plate group 5, and the screened particles can be discharged through the first diversion discharge box 6, the second diversion discharge box 7 and the third diversion discharge box 8;
specifically, the first screen group 3 includes an upper screen 9, a middle screen 10, and a lower screen 11, where the upper screen 9 is used to screen out particles with a mesh number smaller than forty, the middle screen 10 is used to screen out particles with a mesh number between forty and sixty, and the lower screen 11 is used to screen out particles with a mesh number between sixty and eighty; an upper screen plate 9 is positioned at the upper end position of a middle screen plate 10, a lower screen plate 11 is positioned at the lower end position of the middle screen plate 10, an upper discharge channel 13, a middle discharge channel 14 and a lower discharge channel 15 are respectively arranged in the first diversion discharge box 6, the upper discharge channel 13 is communicated with the upper surface of the upper screen plate 9, the middle discharge channel 14 is communicated with the upper surface of the middle screen plate 10, and the lower discharge channel 15 is communicated with the upper surface of the lower screen plate 11; the lower end of the lower sieve plate 11 is also provided with a deflector 12 with the same inclination direction as the lower sieve plate 11, and the lower end of the deflector 12 is provided with an opening.
After the materials are put into the box body 1, the materials are screened once through the first screen plate group 3, particles with the mesh number smaller than forty meshes are screened out to the upper end of an upper screen plate 9 and roll down to the lower end of the upper screen plate 9, and are discharged through an upper discharge channel 13 in the first diversion discharge box 6; particles with a mesh number greater than forty and less than sixty are screened out to the upper end of a middle screen plate 10 and fall down to the lower end of the middle screen plate 10, are discharged through a middle discharge channel 14 in the first diversion discharge box 6, particles with a mesh number greater than sixty and less than eighty are screened out to the upper end of a lower screen plate 11 and fall down to the lower end of the lower screen plate 11, are discharged through a lower discharge channel 15 in the first diversion discharge box 6, and particles with a mesh number greater than eighty are guided by a guide plate 12 to fall down and are screened for the second time through the second screen plate group 4.
Specifically, the second screen plate group 4 includes two upper screen plates 16 and two lower screen plates 17, the two upper screen plates 16 are located at the upper end positions of the two lower screen plates 17, two upper discharge channels 19 and two lower discharge channels 20 are respectively provided in the second tapping bin 7, the two upper discharge channels 19 are communicated with the upper surfaces of the two upper screen plates 16, the two lower discharge channels 20 are communicated with the upper surfaces of the two lower screen plates 17, two guide plates 18 with the same inclination direction as the two lower screen plates 17 are further provided at the lower ends of the two lower screen plates 17, and an opening is provided at the lower end of the two guide plates 18.
After the materials are screened for the first time by the first screen plate group 3, the materials are screened for the second time by the second screen plate group 4; particles with the mesh number greater than eighty meshes and smaller than one hundred meshes are screened out to the upper ends of the two upper screen plates 16 and roll down to the lower end of the two upper screen plates 16, are discharged through the two upper discharge channels 19 in the second separation feed box 7, particles with the mesh number greater than one hundred meshes and smaller than one hundred twenty meshes are screened out to the upper ends of the two lower screen plates 17 and roll down to the lower end of the two lower screen plates 17, are discharged through the two lower discharge channels 20 in the second separation feed box 7, and particles with the mesh number greater than one hundred twenty meshes are guided by the two guide plates 18 to roll down and are screened three times through the third screen plate group 5.
Specifically, the third screen plate group 5 includes three upper screen plates 21, three lower screen plates 22, three guide plates 23, three upper screen plates 21 are located at the upper end positions of three lower screen plates 22, three guide plates 23 are located at the lower end positions of three lower screen plates 22, three guide plates 23 with the same inclination direction as the three lower screen plates 22 are further arranged at the lower end positions of three lower screen plates 22, three upper discharge channels 24, three discharge channels 25 and three lower discharge channels 26 are respectively arranged in the third split discharge box 8, the three upper discharge channels 24 are communicated with the upper surfaces of the three upper screen plates 21, the three discharge channels 25 are communicated with the upper surfaces of the three lower screen plates 22, and the three lower discharge channels 26 are communicated with the upper surfaces of the three guide plates 23.
After the materials are screened once by the second sieve plate group 4, the materials are screened three times by the third sieve plate group 5; particles with the mesh number greater than one hundred twenty mesh and less than one hundred forty mesh are screened out to the upper end of the three upper screen plates 21 and fall to the lower end of the three upper screen plates 21, are discharged through the three upper discharge channels 24 in the third diversion discharge box 8, particles with the mesh number greater than one hundred forty mesh and less than one hundred sixty mesh are screened out to the upper end of the three lower screen plates 22 and fall to the lower end of the three lower screen plates 22, are discharged through the three discharge channels 25 in the third diversion discharge box 8, and particles with the mesh number greater than one hundred sixty mesh are discharged through the three lower discharge channels 26 in the third diversion discharge box 8 through the guide directions of the three guide plates 23.
For the convenience is changed the sieve, the outside of box 1 just is located the position department of the higher one end of first sieve group 3, second sieve group 4, third sieve group 5 and has all been seted up installing port 27, inside the box 1 was inserted to sieve accessible installing port 27, wherein the inside both sides of box 1 all are provided with spout 31, sieve and spout 31 sliding connection, support the sieve through spout 31, the outside of installing port 27 is provided with baffle 28, remove spacingly through baffle 28 to the inserted sieve, the sieve takes place to remove when avoiding processing, the lower extreme and the box 1 rotation of baffle 28 are connected, the upper end of baffle 28 is connected with box 1 through buckle 29. Wherein, the buckle 29 is in sliding connection with the box body 1, the buckle seat 30 is fixed on the upper part of the baffle 28, and the buckle 29 is in buckling connection with the buckle seat 30.
After the screen plate is installed, the baffle 28 is turned upwards to block the installation opening 27, so that the effect of limiting the movement of the screen plate is achieved, the upper end of the baffle 28 is limited by buckling the sliding buckle 29 with the buckling seat 30 on the baffle 28, and the fixing of the baffle 28 is completed.
From the above, it can be seen that:
the utility model aims at the technical problems that: production personnel are inconvenient to take out alloy particles on different filter plates from a screening box, the material taking process is long in delay time, and screening efficiency is restricted; the technical scheme of each embodiment is adopted. Meanwhile, the implementation process of the technical scheme is as follows:
when the novel sieve plate type multi-purpose material screening device is used, materials are put into the box body 1 through the putting port 2, screened through the first sieve plate group 3, discharged through the first diversion discharging box 6, particles smaller than forty meshes, forty meshes to sixty meshes and sixty meshes can be screened out through the first screening, the rest materials are screened out through the second sieve plate group 4 for the second time, discharged through the second diversion discharging box 7, particles from eighty meshes to one hundred meshes and one hundred twenty meshes can be screened out through the second screening, the rest materials are screened out through the third sieve plate group 5 for the third screening, discharged through the third diversion discharging box 8, and particles from one hundred twenty meshes to one hundred forty meshes, one hundred forty meshes to one hundred sixty meshes and more than one hundred sixty meshes can be screened out through the third screening;
when the screen plate is installed, the screen plate is inserted into the box body 1 through the installation opening 27, the screen plate is supported through the sliding groove 31, the baffle 28 is turned upwards, the blocking of the installation opening 27 is completed, the upper end of the baffle 28 is fixed through the buckle 29, and the installation of the screen plate is completed.
Through above-mentioned setting, this application must solve above-mentioned technical problem, simultaneously, realizes following technical effect:
through the structural design of first sieve group 3, second sieve group 4, third sieve group 5 for the device can carry out multiple screening to the material, makes the device screen out more classification with the material, is convenient for carry out the processing of raw materials to the fireworks firecracker goods of more specifications, and through the structure cooperation of first reposition of redundant personnel discharging case 6, second reposition of redundant personnel discharging case 7, third reposition of redundant personnel discharging case 8, can carry out categorised ejection of compact to the classification of screening out for the device carries out the ejection of compact when sustainable processing, has improved the efficiency of processing.
The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a magnalium granule preparation facilities, includes box (1), its characterized in that, the inside of box (1) has set gradually first sieve group (3), second sieve group (4), third sieve group (5) from top to bottom, first sieve group (3), second sieve group (4), third sieve group (5) are the slope setting, the outside of box (1) and with first sieve group (3), second sieve group (4), third sieve group (5) lower one end position department is provided with first reposition of redundant personnel discharging case (6), second reposition of redundant personnel discharging case (7), third reposition of redundant personnel discharging case (8) respectively;
the utility model discloses a box, including box (1), box, buckle (29), box, buckle (28), lower extreme and box (1) rotate to be connected, the outside of box (1) just is located first sieve group (3), second sieve group (4), the position department of the higher one end of third sieve group (5) has all been seted up installing port (27), the outside of installing port (27) is provided with baffle (28), the upper end of baffle (28) is connected with box (1) through buckle (29).
2. A magnesium aluminium alloy granule manufacturing apparatus according to claim 1, characterized in that the first screen group (3) is arranged to be high on the left and low on the right, the second screen group (4) is arranged to be high on the left and low, and the third screen group (5) is arranged to be high on the left and low on the right.
3. A device for preparing magnesium aluminum alloy particles according to claim 1, wherein the first sieve plate group (3) comprises an upper sieve plate (9), a middle sieve plate (10) and a lower sieve plate (11), the upper sieve plate (9) is positioned at the upper end position of the middle sieve plate (10), the lower sieve plate (11) is positioned at the lower end position of the middle sieve plate (10), an upper discharging channel (13), a middle discharging channel (14) and a lower discharging channel (15) are respectively arranged in the first diversion discharging box (6), the upper discharging channel (13) is communicated with the upper surface of the upper sieve plate (9), the middle discharging channel (14) is communicated with the upper surface of the middle sieve plate (10), and the lower discharging channel (15) is communicated with the upper surface of the lower sieve plate (11); the lower end position of the lower sieve plate (11) is also provided with a guide plate (12) with the same inclination direction as the lower sieve plate (11), and one lower end of the guide plate (12) is provided with an opening.
4. The magnesium aluminum alloy particle preparation device according to claim 1, wherein the second sieve plate group (4) comprises two upper sieve plates (16) and two lower sieve plates (17), the two upper sieve plates (16) are located at the upper end positions of the two lower sieve plates (17), two upper discharging channels (19) and two lower discharging channels (20) are respectively formed in the second separating and discharging bin (7), the two upper discharging channels (19) are communicated with the upper surfaces of the two upper sieve plates (16), the two lower discharging channels (20) are communicated with the upper surfaces of the two lower sieve plates (17), two guide plates (18) with the same inclination direction as the two lower sieve plates (17) are further arranged at the lower ends of the two guide plates (18), and openings are formed in the lower ends of the two guide plates (18).
5. The magnesium aluminum alloy particle preparation device according to claim 1, wherein the third sieve plate group (5) comprises three upper sieve plates (21), three lower sieve plates (22) and three guide plates (23), the three upper sieve plates (21) are located at the upper end positions of the three lower sieve plates (22), the three guide plates (23) are located at the lower end positions of the three lower sieve plates (22), the three guide plates (23) with the same inclination direction as the three lower sieve plates (22) are further arranged at the lower end positions of the three lower sieve plates (22), three upper discharge channels (24), three discharge channels (25) and three lower discharge channels (26) are respectively arranged in the third split discharge box (8), the three upper discharge channels (24) are communicated with the upper surfaces of the three upper sieve plates (21), the three discharge channels (25) are communicated with the upper surfaces of the three lower sieve plates (22), and the three lower discharge channels (26) are communicated with the upper surfaces of the three guide plates (23).
6. The magnesium aluminum alloy particle preparation device according to claim 1, wherein a delivery port (2) is arranged at the top end of the box body (1).
7. The magnesium aluminum alloy particle preparation device according to claim 1, wherein the buckle (29) is in sliding connection with the box body (1), the buckle seat (30) is fixed on the upper portion of the baffle plate (28), and the buckle (29) is in buckling connection with the buckle seat (30).
CN202222923424.8U 2023-04-10 2023-04-10 Magnesium aluminum alloy granule preparation facilities Active CN219003640U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202222923424.8U CN219003640U (en) 2023-04-10 2023-04-10 Magnesium aluminum alloy granule preparation facilities

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202222923424.8U CN219003640U (en) 2023-04-10 2023-04-10 Magnesium aluminum alloy granule preparation facilities

Publications (1)

Publication Number Publication Date
CN219003640U true CN219003640U (en) 2023-05-12

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CN202222923424.8U Active CN219003640U (en) 2023-04-10 2023-04-10 Magnesium aluminum alloy granule preparation facilities

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