CN212713286U

CN212713286U - Three-dimensional integrated processing production line for common gypsum, special gypsum and machine-made sand

Info

Publication number: CN212713286U
Application number: CN202021858096.2U
Authority: CN
Inventors: 危春国
Original assignee: Langshida Hubei Intelligent Technology Co ltd; Lstar Intelligent Equipment Engineering Jiangsu Co ltd
Current assignee: Langshida Hubei Intelligent Technology Co ltd; Lstar Intelligent Equipment Engineering Jiangsu Co ltd
Priority date: 2020-08-31
Filing date: 2020-08-31
Publication date: 2021-03-16
Anticipated expiration: 2030-08-31

Abstract

The utility model discloses a three-dimensional integrative processing production line of ordinary gypsum and special gypsum and machine-made sand, include: the machine-made sand production unit and the common gypsum and special gypsum processing production unit connected with the machine-made sand production unit are connected; the machine-made sand production unit comprises a machine-made sand screening mechanism and a powder concentrator arranged at the downstream of the machine-made sand screening mechanism; the machine-made sand screening mechanism comprises a screening bin, a discharge distribution bin and a receiving hopper, wherein the discharge distribution bin and the receiving hopper are matched with the screening bin in a supporting mode; the ordinary gypsum and special gypsum processing and producing unit comprises a sand material feeding assembly, and a special gypsum producing mechanism and an ordinary gypsum producing mechanism which are connected with the sand material feeding assembly in a connecting mode.

Description

Three-dimensional integrated processing production line for common gypsum, special gypsum and machine-made sand

Technical Field

The utility model relates to an engineering machine tool technical field especially relates to a three-dimensional integrated processing production line of ordinary gypsum and special gypsum and machine-made sand.

Background

In the production process of gypsum, common gypsum is formed by mixing and processing common sand powder and ingredients, and special gypsum has smaller and finer grain size than common gypsum. In the process of processing different types of gypsum, the sand powder for making gypsum needs to be screened at first, so that the corresponding gypsum is made from the screened sand powder. Therefore, the design can possess sieve material and the production line of different types of gypsum processing production simultaneously can improve the efficiency of holistic gypsum production. In addition, through setting up the structure that can produce two kinds of different gypsum in same production line, can also effectively reduce manufacturing cost.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a three-dimensional integrative processing production line of ordinary gypsum and special gypsum and machine-made sand to solve the technical problem who improves gypsum processing production efficiency.

The utility model discloses a three-dimensional integrative processing production line of ordinary gypsum and special gypsum and machine-made sand is realized like this:

the utility model provides a three-dimensional integrative processing production line of ordinary gypsum and special gypsum and machine-made sand, includes: the machine-made sand production unit and the common gypsum and special gypsum processing production unit connected with the machine-made sand production unit are connected;

the machine-made sand production unit comprises a machine-made sand screening mechanism and a powder concentrator arranged on the downstream of the machine-made sand screening mechanism;

the machine-made sand screening mechanism comprises a screening bin, a discharge distribution bin and a receiving hopper, wherein the discharge distribution bin and the receiving hopper are matched with the screening bin in a supporting mode; the receiving hopper is positioned below the bottom plate of the screening bin to receive sand; the powder concentrator comprises a feeding groove and a powder concentrating cavity which are communicated; wherein the feeding groove is connected with the receiving hopper in a supporting way;

the ordinary gypsum and special gypsum processing and producing unit comprises a sand material feeding assembly, and a special gypsum producing mechanism and an ordinary gypsum producing mechanism which are connected with the sand material feeding assembly in a connecting way;

the sand material feeding assembly comprises a first hopper lifter connected with the powder selecting cavity and a vibrating screen connected with the first hopper lifter; the vibrating screen is communicated with a first material cylinder and a second material cylinder through a material pipe respectively;

the special gypsum production mechanism comprises a first powder metering scale connected with the first charging barrel, a first powder adding assembly connected with the first powder metering scale, and a first mixer connected with the first powder metering scale in a supporting manner;

the common gypsum production mechanism comprises a second powder metering scale connected with the second charging barrel, a second mixer connected with the second powder metering scale, and a third powder metering scale connected with the second mixer; and the third powder metering scale is also connected with a second powder adding component.

In a preferred embodiment of the invention, three screen plates are arranged in the screening bin at intervals; a screen frame is arranged at the bottom of the screen storage bin; the three screen plates are distributed at intervals along the height direction of the screen bin; the meshes of the three screen plates are gradually reduced from the top of the screening bin to the bottom; the meshes of the screen frame are smaller than the meshes of the screen plate adjacent to the bottom plate;

and three distribution cavities which are in one-to-one correspondence with the three screen plates are arranged in the discharge distribution bin.

In a preferred embodiment of the invention, a feed inlet is arranged at the top of the feed chute and receives the discharge end of the receiving hopper; and

the bottom of the feeding groove is fixedly connected with the top of the powder selecting cavity; the bottom of the powder selecting cavity is provided with a discharge port which is used for receiving the machine-made sand containing bin; the machine-made sand accommodating bin is connected with a hopper of the first bucket elevator through a belt conveyor;

an air suction groove is arranged in the powder selecting cavity, and an air suction opening is formed in one end of the air suction groove;

an upper air supply port is arranged on the side wall of the feeding groove, and a lower air supply port is arranged on the side wall of the powder selecting cavity.

In a preferred embodiment of the present invention, three of the screen plates are arranged in parallel; and

the three screen plates are all distributed along the screen material bin in an inclined mode; and is

The end parts of the three screen plates close to the discharge distribution bin are lower than the end parts of the screen plates far away from the discharge distribution bin.

In the preferred embodiment of the invention, the bottom of the distribution cavity of the screen plate corresponding to the highest position in the three screen plates is provided with a first discharge pipe;

the bottom of the distribution cavity of the sieve plate corresponding to the middle position of the three sieve plates is connected with a second discharge pipe and a third discharge pipe in parallel; and

the bottom of the distribution cavity of the sieve plate at the lowest position corresponding to the three sieve plates is matched and connected with a fourth discharge pipe and a fifth discharge pipe in parallel;

the bottom of the distribution cavity of the screen plate at the highest position in the three screen plates is connected with a first discharge pipe in a matching way;

the first discharging pipe and the second discharging pipe are both connected with a first discharging box body; the discharge end of the first discharge box body is connected with a crusher; and

the fifth discharge pipe is connected with a second discharge box body, and the second discharge box body is connected with the machine-made sand containing bin through a connecting pipe;

the second discharge pipe is also matched and connected with a first gate valve which is suitable for controlling the on-off of the second discharge pipe; and

the fifth discharge pipe is also connected with a second gate valve which is suitable for controlling the on-off of the fifth discharge pipe.

In a preferred embodiment of the invention, the first material cylinder is connected with a first powder material metering scale through a first material conveying pipe;

the first powder adding assembly comprises at least one first additive feeding hopper and at least one new powder adding bin which are respectively connected with the first powder metering scale.

In a preferred embodiment of the present invention, the second powder adding assembly comprises at least one second additive feeding hopper respectively connected with a third powder measuring scale;

and at least one new powder feeding bin is also connected with a third powder metering scale through a powder conveying pipe.

In a preferred embodiment of the invention, a first packing machine is also received below the first mixing machine; and

the second mixes the machine and still is connected with the finished product storehouse through screw conveyer, the below in finished product storehouse is accepted the second packagine machine.

In a preferred embodiment of the invention, the second charging barrel passes through a second bucket elevator to put powder into the dry sand separation bin;

the second charging barrel is connected with the hopper of the second bucket elevator, and a discharging chute of the second bucket elevator is connected with the dry sand separation bin;

the dry sand separation bin is connected with the second powder material metering scale.

In a preferred embodiment of the invention, the hopper of the second bucket elevator is also connected with a third charging barrel; and the third charging barrel is connected with a discharging chute of the first bucket elevator.

By adopting the technical scheme, the utility model discloses following beneficial effect has: the utility model discloses a three-dimensional integrative processing production line of ordinary gypsum and special gypsum and mechanism sand screens the sand material through mechanism sand production unit and produces the sand powder material that is suitable for processing gypsum with the screening processing. The sand powder material that will process out through mechanism sand production unit drops into ordinary gypsum and special gypsum processing production unit again, through the sand material feeding component that is suitable for that the design carries out the screening to the sand powder material to and special gypsum production mechanism and ordinary gypsum production mechanism that link to each other respectively with sand material feeding component, make the utility model discloses a three-dimensional integrated processing production line of ordinary gypsum and special gypsum and mechanism sand possesses the production of sand material screening and ordinary gypsum and special gypsum simultaneously, not only can simplify the structure of holistic production line, practices thrift the manufacturing cost of production line, can improve the overall efficiency of gypsum production moreover.

Drawings

FIG. 1 is a schematic view of a first perspective of a three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

FIG. 2 is a schematic view of a first viewing angle of a common gypsum and special gypsum processing and producing unit of a three-dimensional integrated processing production line of common gypsum, special gypsum and machine-made sand of the present invention;

FIG. 3 is a schematic view of a second perspective of the ordinary gypsum and special gypsum processing and producing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

FIG. 4 is a schematic view of a third perspective of the ordinary gypsum and special gypsum processing and producing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

fig. 5 is a schematic view of a first viewing angle of a machine-made sand processing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

fig. 6 is a second view schematic diagram of the machine-made sand processing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

fig. 7 is a first view schematic diagram of a discharging distribution bin of a machine-made sand processing unit of the three-dimensional integrated processing production line for common gypsum, special gypsum and machine-made sand of the utility model;

fig. 8 is a second view schematic diagram of the discharge distribution bin of the machine-made sand processing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

FIG. 9 is a front view of the powder concentrator of the discharging distribution bin of the machine-made sand processing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

FIG. 10 is a left side view of FIG. 9;

FIG. 11 is a right side view of FIG. 9;

fig. 12 is a schematic view of the internal structure of the powder concentrator of the discharging distribution bin of the machine-made sand processing unit of the three-dimensional integrated processing production line for ordinary gypsum, special gypsum and machine-made sand of the present invention;

fig. 13 is the structure schematic diagram of the discharging distribution bin of the machine-made sand processing unit of the three-dimensional integrated processing production line of the common gypsum, the special gypsum and the machine-made sand of the utility model.

In the figure: the material inlet comprises a material inlet groove 1, a powder selecting cavity 2, a material inlet 11, a material inlet adjusting plate 12, a material outlet 21, an air draft groove 3, an air draft opening 31, a filter plate assembly 4, an upper air supplement opening 5, an upper air supplement adjusting plate 51, a lower air supplement opening 6, a lower air supplement adjusting plate 61, a rectangular frame 41, a baffle plate 42, an access opening 8, an air pipe 15, a stone powder recovery bin 16, a crusher 18, a connecting pipe 19, a screening bin 100, a material inlet 101, a screen plate 102, a screen frame 103, a material discharging distribution bin 200, a distribution cavity 201, a first material outlet pipe 202, a second material outlet pipe 203, a third material outlet pipe 205, a fourth material outlet pipe 206, a fifth material outlet pipe 207, a first connecting pipe 208, a second connecting pipe 210, a first gate valve 211, a second gate valve 212, a first material discharge box 213, a second material discharge box 215, a material receiving hopper 300, a flexible connecting layer 400, a first hopper lifter 600, a vibrating screen 700, a material pipe 701, a, The device comprises a first powder metering scale 901, a first mixer 902, a second powder metering scale 903, a third powder metering scale 904, a first additive feeding hopper 906, a new additive storage hopper 907, a second additive feeding hopper 908, a first packing machine 909, a spiral conveyer 910, a finished product storage hopper 911, a second packing machine 912, a second bucket elevator 913, a dry sand separation storage hopper 915, a third charging barrel 916, a second mixer 917 and a belt conveyer 1000.

Detailed Description

In order that the present invention may be more readily and clearly understood, the following detailed description of the present invention is provided in connection with the accompanying drawings.

Referring to fig. 1 to 13, the present embodiment provides a three-dimensional integrated processing production line for general gypsum, special gypsum and machine-made sand, including: a machine-made sand production unit and a common gypsum and special gypsum processing production unit connected with the machine-made sand production unit. In the embodiment, the sand material is screened by the mechanical sand production unit to produce the sand powder suitable for processing gypsum through screening and processing. And then the sand powder processed by the machine-made sand production unit is put into a common gypsum and special gypsum processing production unit.

The ordinary gypsum and special gypsum processing and producing unit comprises a sand material feeding assembly, and a special gypsum producing mechanism and an ordinary gypsum producing mechanism which are connected with the sand material feeding assembly.

Specifically, firstly, the sand feeding assembly comprises a first bucket elevator 600 and a vibrating screen 700 connected with the first bucket elevator 600; the vibrating screen 700 is communicated with a first material cylinder 801 and a second material cylinder 802 through a material pipe 701 respectively; that is, the vibrating screen 700 further screens the sand powder conveyed by the first hopper 600 to distinguish coarse sand powder from fine sand powder, where the coarse sand powder passes through the vibrating screen 700 and enters the second cylinder 802, and the fine sand powder passes through the vibrating screen 700 and enters the first cylinder 801.

Secondly, the special gypsum production mechanism comprises a first powder metering scale 901 connected with the first charging barrel 801, a first powder adding component connected with the first powder metering scale 901, and a first mixer 902 connected with the first powder metering scale 901 in a supporting manner.

Furthermore, the ordinary gypsum production mechanism includes a second powder weigher 903 connected to the second cylinder 802, a second mixer 917 connected to the second powder weigher 903, and a third powder weigher 904 connected to the second mixer 917; the third powder weigher 904 is also connected to a second powder adding assembly.

A machine-made sand production unit comprising: a machine-made sand screening mechanism and a powder concentrator arranged at the downstream of the machine-made sand screening mechanism. The machine-made sand screening mechanism comprises a screening bin 100, a discharge distribution bin 200 and a receiving hopper 300, wherein the discharge distribution bin 200 and the receiving hopper are matched with the screening bin 100 in a receiving mode. A feeding opening 101 is arranged at the top of the screening material bin 100 and at the end of the screening material bin 100 far away from the discharging distribution bin 200. Three screen plates 102 are arranged in the screen bin 100 at intervals; and a screen frame 103 is arranged at the bottom of the screening bin 100; the three screen plates 102 are distributed at intervals along the height direction of the screen storage bin 100, and it should be noted here that the three screen plates 102, in cooperation with the screen frame 103 at the bottom of the screen storage bin 100, actually divide the whole screen storage bin 100 into four divided regions along the height direction thereof; the meshes of the three screen plates 102 are gradually reduced from the top to the bottom of the screen material bin 100; and the mesh of the screen frame 103 is smaller than the mesh of the screen plate 102 adjacent to the bottom plate, that is, after sand enters the screen storage bin 100, the sand can respectively enter different separation intervals correspondingly according to the difference of the particle sizes.

Three distribution cavities 201 which are in one-to-one correspondence with the three screen plates 102 are arranged in the discharge distribution bin 200, namely, the three distribution cavities 201 are in one-to-one correspondence with the separation sections formed by the three screen plates 102 in the screen material bin 100 to form a bearing relation so that sand materials can enter the distribution cavities 201. The receiving hopper 300 is located below the bottom plate of the screening silo 100 to receive sand, and the receiving hopper 300 is actually used to receive sand finally passing through the screen frame 103. The powder concentrator comprises a feeding groove 1 and a powder concentrating cavity 2 which are communicated; wherein the feeding chute 1 is connected with the receiving hopper 300 in a receiving way.

The top of feed chute 1 is provided with feed inlet 11, and the machine-made sand granule and the mountain flour granule of discharge from connecing in the hopper get into selection powder chamber 2 from feed inlet 11, and ring flange fixed connection is passed through with the top in selection powder chamber 2 in the bottom of feed chute 1, and the discharge gate 21 has been seted up to the bottom in selection powder chamber 2, and this discharge gate 21 accepts the machine-made sand and holds the storehouse, and the machine-made sand of this department holds the storehouse and accepts through band conveyer 1000 and the hopper of first bucket elevator 600. An air suction groove 3 is arranged in the powder selecting cavity 2, an air suction opening 31 is formed in one end of the air suction groove 3, and the air suction opening 31 is connected with a stone powder recovery bin 16 through an air pipe 15.

In addition, the other end of convulsions groove 3 is provided with filter subassembly 4, the draught fan during operation, the mountain flour granule passes filter subassembly 4 and takes out from selecting powder chamber 2, mechanism sand granule falls from selecting powder chamber 2's discharge gate 21, be provided with on the lateral wall of feed chute 1 and mend wind gap 5, be provided with lower mend wind gap 6 on selecting powder chamber 2's the lateral wall, respectively from last mend wind gap 5 with 6 blow-in of mend wind gap down, the volume of wind of taking out in convulsions groove 3 at this moment is offset partly, make the dynamics of convulsions reduce, only less mountain flour granule is taken out from suction opening 31 this moment, and great granule then falls from selecting powder chamber 2.

The filter plate assembly 4 comprises a rectangular frame 41 and a plurality of baffles 42, the rectangular frame 41 is fixedly connected with the air draft groove 3, the baffles 42 are fixed on the rectangular frame 41 from top to bottom at intervals in sequence, the baffles 42 are obliquely arranged, and small particles are drawn out from gaps among the baffles 42.

The below of feed inlet 11 is provided with feeding regulating plate 12, and the both ends of feeding regulating plate 12 are passed through the bearing and are rotated and connect on the lateral wall of feed chute 1, and the one end of feeding regulating plate 12 is provided with first adjustment handle 71, and feeding regulating plate 12 is used for adjusting the aperture of feed inlet 11 to adjust what of feeding.

An upper air supplement adjusting plate 51 is arranged above the upper air supplement opening 5, two ends of the upper air supplement adjusting plate 51 are rotatably connected to the side wall of the upper air supplement opening 5 through bearings, and a second adjusting handle 72 is arranged at one end of the upper air supplement adjusting plate 51. The upper air supplement adjusting plate 51 is used for adjusting the air volume of the inlet air, if larger stone powder particles need to be extracted, the air volume of the air supplement is adjusted to be smaller, and if smaller stone powder particles need to be extracted, the air volume of the air supplement is adjusted to be larger.

The lower air supply opening 6 is positioned below the air suction groove 3, a lower air supply adjusting plate 61 is arranged above the lower air supply opening 6, two ends of the lower air supply adjusting plate 61 are rotatably connected to the side wall of the lower air supply opening 6 through bearings, and one end of the lower air supply adjusting plate 61 is provided with a third adjusting handle 73. The lower air supply adjusting plate 61 is used for adjusting the air volume of the inlet air, if larger stone powder particles need to be extracted, the air volume of the air supply is adjusted to be smaller, and if smaller stone powder particles need to be extracted, the air volume of the air supply is adjusted to be larger.

It should be further noted that an access opening 8 is formed in the side wall of the powder selecting cavity 2 and is opened when the powder selecting cavity needs to be overhauled.

In an alternative embodiment, which is exemplified by referring to the drawings, three screen plates 102 are arranged in parallel; and three screen plates 102 are all distributed along the screen storage bin 100 in an inclined way; and the ends of the three screen panels 102 close to the discharge distribution bin 200 are lower than the ends of the screen panels 102 far from the discharge distribution bin 200. The inclined arrangement of the screen plate 102 is advantageous in that the sand can rapidly enter the corresponding distribution chamber 201 of the discharge distribution bin 200 by utilizing the gravity of the sand. The screen frame 103 of this embodiment may be an inclined structure or a parallel structure with respect to the horizontal plane, and therefore the receiving hopper 300 for receiving sand on the screen frame 103 is located below the screen frame 103, so that the use requirements of this embodiment are met by both the inclined screen frame 103 and the horizontally arranged screen frame 103, and this embodiment is not limited in any way.

In an alternative embodiment, the receiving hopper 300 is coupled to the bottom of the screen silo 100 by a flexible connecting layer 400. The flexible connection layer 400 herein may be a flexible cloth cover or a flexible plastic cover, which is not limited to this embodiment, and the significance of this design is that for the screen material bin 100 of this embodiment, in order to improve the screening efficiency of sand material in the screen material bin 100, a driving structure suitable for causing the screen material bin 100 to generate micro vibration may be optionally disposed on the outer side wall of the screen material bin 100, for example, but not limited to, a vibration motor, that is, in this case, there is a vibration condition in the screen material bin 100 during actual use, so that, through the flexible connection layer 400 herein, on one hand, the receiving hopper 300 can be prevented from generating vibration synchronized with the screen material bin 100 to increase the resistance when the screen material bin 100 vibrates, and on the other hand, the vibration of the receiving hopper 300 can be prevented from affecting the stability of connection between the receiving hopper 300 and other structures connected to the receiving hopper 300. That is, the flexible connection layer 400 may play a role of buffering vibration of the sieve bin 100, so that the vibration of the sieve bin 100 does not generate vibration of the receiving hopper 300.

It should be further noted that the bottom of the distribution chamber 201 corresponding to the screen plate 102 at the highest position in the three screen plates 102 is connected with a first discharge pipe 202; a second discharge pipe 203 and a third discharge pipe 205 are connected in parallel to the bottom of the distribution chamber 201 of the sieve plate 102 located at the middle position among the three sieve plates 102; and a fourth discharge pipe 206 and a fifth discharge pipe 207 are coupled in parallel to the bottom of the distribution chamber 201 corresponding to the lowest screen plate 102 of the three screen plates 102.

Furthermore, the third discharge pipe 205 is connected to a fifth discharge pipe 207 via a first connecting pipe 208; and the fourth tapping pipe 206 is connected to the second tapping pipe 203 via a second connecting pipe 210. The first discharge pipe 202 and the second discharge pipe 203 are both connected with a first discharge box body 213, and the discharge end of the first discharge box body 213 is connected with the crusher 18; the fifth discharge pipe 207 is connected to the second discharge tank 215, and the second discharge tank 215 receives the machine-made sand storage bin through the connection pipe 19. The second discharge pipe 203 is also matched with a first gate valve 211 which is suitable for controlling the on-off of the second discharge pipe 203; and the fifth discharge pipe 207 is also connected with a second gate valve 212 which is suitable for controlling the on-off of the fifth discharge pipe 207.

That is, in fact, for the sand of the present embodiment, the sand passing through the screen material bin 100 may finally enter three different areas, namely the first discharge box 213, the second discharge box 215 and the receiving hopper 300, and the sand passing through the discharge distribution bin 200 finally goes to the first discharge box 213, the second discharge box 215 or the first discharge box 213.

Specifically, when first gate valve 211 is opened, and under the closed state of second gate valve 212, the sand material that passes through in ejection of compact distribution bin 200 all can enter into first row of workbin body 213 this moment, to whole machine-made sand production unit this moment, can realize the effect of two-stage differentiation to the sand material, and one kind of sand material gets into first row of workbin body 213, and another kind gets into and connects hopper 300. The two-stage distinguishing condition is suitable for places with low sand distinguishing requirements.

When the first gate valve 211 is closed and the second gate valve 212 is opened, the sand in the distribution chamber 201 of the screen plate 102 located at the highest position in the corresponding screen storage 100 in the discharging distribution bin 200 enters the first discharging box body 213, and the sand in the distribution chamber 201 of the screen plate 102 located at the middle position and the lowest position in the discharging distribution bin 200 enters the second discharging box body 215. In this case, for the machine-made sand production unit lower than the whole, three-level distinguishing effect can be achieved for sand materials, i.e., one kind of sand enters the first discharge box body 213, one kind of sand enters the second discharge box body 215, and the other kind of sand enters the receiving hopper 300. The three-level distinguishing condition is suitable for places with relatively high sand distinguishing requirements.

To sum up, that is to the mechanism sand production unit of this embodiment, adopt same set of structure, through the in service behavior of adjustment first push-pull valve 211 and second push-pull valve 212, the sand material screening of two kinds of differences can appear and distinguish the effect, so can improve the application scope of mechanism greatly, do not need two kinds of structures of pertinence development to the use place that the condition was distinguished to the two-stage and the tertiary condition of distinguishing.

The specific implementation principle of the machine-made sand production unit of the embodiment is as follows: the machine-made sand particles and the stone powder particles which are fed into the receiving hopper 300 after sand materials are screened by the screening bin 100 can pass through the powder concentrator, so that the stone powder can finally be fed into the stone powder recovery bin for recovery and reuse, and the machine-made sand is finally recovered by the machine-made sand storage bin. In addition, the sand screened by the screened silo 100 enters the first discharge bin body 213 and then enters the crusher for further crushing for further use.

In detail, the first material cylinder 801 is connected with the first powder material metering scale 901 through a first material conveying pipe 701; and the first powder adding assembly comprises at least one first additive feeding hopper 906 and at least one new additive feeding bin 907 which are respectively connected with the first powder metering scale 901. Namely, the sand powder in the first charging barrel 801, the additive and the newly added powder are thrown into the first mixer 902, so that various powder materials are fully mixed and processed in the first mixer 902 to form the special gypsum, and a first packing machine 909 for packing the special gypsum for conveying is also received below the first mixer 902.

The second powder adding component comprises at least one second additive feeding hopper 908 respectively connected with the third powder metering scale 904; at least one new powder feeding bin 907 is also connected to the third powder weigher 904 via a powder conveying pipe. That is, for the ordinary gypsum production mechanism and the special gypsum production mechanism of this embodiment, the same new powder adding bin 907 is connected, so that the structure can be simplified, and the new powder adding bin 907 is prevented from being reused. The second mixing machine 917 is also connected to a finished product bin 911 via a screw conveyor 910, and a second packing machine 912 is received below the finished product bin 911. That is, the second mixer 917 throws the sand powder in the second charging barrel 802, and the additive and the newly added powder into the second mixing machine, so that various powder materials are fully mixed and processed in the second mixer 917 to form the common gypsum, the second mixer 917 is also connected with a finished product bin 911, and a second packing machine 912 is arranged below the finished product bin 911 and used for packing the common gypsum so as to facilitate conveying.

In an alternative embodiment, the second barrel 802 is connected to the second powder weigher 903 through a second feed pipe 701.

In yet another alternative embodiment, the second barrel 802 is fed through a second hopper lift 913 to deposit powder into the dry sand compartment 915; the second charging barrel 802 is connected with a hopper of a second bucket elevator 913, and a blanking chute of the second bucket elevator 913 is connected with a dry sand separation bin 915; the dry sand separation bin 915 is connected with a second powder material metering scale 903. The dry sand separation bin 915 here comprises two separate bin bodies, one of which is forced to receive the sand powder in the second barrel 802. The hopper of the second hopper elevator 913 is connected with a third charging barrel 916; the third barrel 916 is connected to a discharge chute of the first hopper lift 600. The sand powder in the third barrel 916 enters the other of the dry sand separation bins 915.

It should be noted that the sand powder in the third barrel 916 in this embodiment does not need to be screened by the vibrating screen 700. That is to the utility model discloses a three-dimensional integrative processing lines of ordinary gypsum and special gypsum and mechanism sand both can carry out hierarchical gypsum processing after screening sand powder material, can also directly carry out gypsum processing through not passing through the screening, all satisfy the user demand to the environment of different user demands. That is to say, the embodiment can carry out the processing of ordinary gypsum and special gypsum simultaneously, also can be only ordinary gypsum of production, to this, specific application method can select corresponding production mode according to the actual use demand.

The above embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above embodiments are only examples of the present invention, and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

In the description of the present invention, it is to be understood that the terms indicating orientation or positional relationship are based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplification of description, and do not indicate or imply that the equipment or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate the position or positional relationship based on the position or positional relationship shown in the drawings, or the position or positional relationship which is usually placed when the product of the present invention is used, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific position, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the present disclosure, unless otherwise expressly stated or limited, the first feature may comprise both the first and second features directly contacting each other, and also may comprise the first and second features not being directly contacting each other but being in contact with each other by means of further features between them. Also, the first feature being above, on or above the second feature includes the first feature being directly above and obliquely above the second feature, or merely means that the first feature is at a higher level than the second feature. A first feature that underlies, and underlies a second feature includes a first feature that is directly under and obliquely under a second feature, or simply means that the first feature is at a lesser level than the second feature.

Claims

1. The utility model provides a three-dimensional integrative processing production line of ordinary gypsum and special gypsum and machine-made sand which characterized in that includes: the machine-made sand production unit and the common gypsum and special gypsum processing production unit connected with the machine-made sand production unit are connected;

2. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand according to claim 1, wherein three screen plates are arranged in the screen bin at intervals; a screen frame is arranged at the bottom of the screen storage bin; the three screen plates are distributed at intervals along the height direction of the screen bin; the meshes of the three screen plates are gradually reduced from the top of the screening bin to the bottom; the meshes of the screen frame are smaller than the meshes of the screen plate adjacent to the bottom plate;

3. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand according to claim 2, wherein a feed port is arranged at the top of the feed chute and receives a discharge end of the receiving hopper; and

4. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand according to claim 3, wherein three screen plates are arranged in parallel; and

5. The three-dimensional integrated processing production line for the ordinary gypsum, the special gypsum and the machine-made sand according to any one of claims 3 or 4, wherein a first discharge pipe is connected to the bottom of a distribution cavity of a screen plate at the highest position in the three screen plates;

6. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand as claimed in claim 5, wherein the first charging barrel is connected with a first powder material metering scale through a first material conveying pipe;

7. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand according to claim 6, wherein the second powder adding component comprises at least one second additive feeding hopper which is respectively connected with a third powder metering scale;

8. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand according to claim 1, wherein a first packing machine is further accepted below the first mixer; and

9. The three-dimensional integrated processing production line for the ordinary gypsum, the special gypsum and the machine-made sand according to claim 1, wherein the second charging barrel is used for putting powder into the dry sand separation bin through a second bucket elevator;

10. The three-dimensional integrated processing production line for the common gypsum, the special gypsum and the machine-made sand according to claim 9, wherein a hopper of the second hopper lifter is further connected with a third charging barrel;

and the third charging barrel is connected with a discharging chute of the first bucket elevator.