CN112808579B - Mineral aggregate wet material autosegregation equipment - Google Patents

Abstract

The invention discloses mineral aggregate wet material automatic separation equipment, which comprises a fixed frame and a bin, wherein the bin is arranged on the fixed frame, an automatic discharging mechanism is arranged in the bin, a grading type screening mechanism is arranged at the lower part of the bin, a wet material recovery processing mechanism is arranged at one side of the grading type screening mechanism, the grading type screening mechanism is arranged at the lower part of the bin, the automatic discharging mechanism is arranged in the bin, the wet material recovery processing mechanism is arranged at one side of the grading type screening mechanism, aggregate to be processed is put into the bin, the aggregate in the bin is quantitatively conveyed through the automatic discharging mechanism, the grading type screening mechanism is utilized for screening the aggregate, and massive wet materials enter the wet material recovery processing mechanism for dehumidification and drying processing under the vibration effect, so that the resource utilization rate is improved, the structure is simple, and the automation degree is high.

Description

Mineral aggregate wet material autosegregation equipment

Technical Field

The invention relates to the technical field of mineral processing, in particular to automatic mineral aggregate wet material separation equipment.

Background

The granular materials which play a role in framework and filling in the concrete and the mortar are called aggregate, and the aggregate comprises fine aggregate and coarse aggregate, wherein the particle diameter of the fine aggregate is between 0.16 and 5 and mm, natural sand such as river sand, sea sand, valley sand and the like is generally adopted, and when the natural sand is lacking, hard rock can be used for grinding artificial sand; the coarse aggregate particle diameter is larger than 5 mm, the common broken stone and pebble are used, under the same conditions, the strength of broken stone concrete is higher than that of pebble concrete, but broken stone is formed by crushing rock, the cost is higher than that of pebble, the common coarse aggregate in lightweight aggregate concrete is natural porous rock such as pumice, artificial porous aggregate such as ceramsite and expansion slag, the aggregate with the particle diameter of less than 4.75 mm is called fine aggregate, commonly called sand, the sand is classified into natural sand and artificial sand according to the production source, the natural sand is rock particles which are formed by natural weathering, water flow carrying and sorting and stacking and have the particle diameter of less than 4.75 mm, but the particles of soft rock and weathered rock are not included, the natural sand comprises river sand, lake sand, mountain sand and desalted sea sand, the artificial sand is the aggregate which is subjected to a mechanism of soil removal treatment, and is generally called by mixed sand, and in the mineral aggregate processing production process, therefore, the aggregate is easy to form a block wet aggregate, the wet aggregate doped in the block aggregate needs to be separated in the subsequent processing process, the wet aggregate is further, the storage stability of the block aggregate is improved, the conventional wet aggregate is not easy to separate the wet aggregate, the problem of the conventional equipment is solved, and the wet aggregate cannot be separated and the wet aggregate is difficult to be produced.

Disclosure of Invention

The invention aims to solve the problems, designs automatic mineral aggregate wet material separation equipment, and solves the problems in the background technology.

The technical scheme of the invention for achieving the purpose is as follows: the mineral aggregate wet material automatic separation equipment comprises a fixed frame and a bin, wherein the bin is arranged on the fixed frame, an automatic discharging mechanism is arranged in the bin, a grading type screening mechanism is arranged at the lower part of the bin, and a wet material recycling mechanism is arranged at one side of the grading type screening mechanism;

the automatic discharging mechanism comprises: the quantitative feeding device comprises a driving control structure and a quantitative feeding structure, wherein the driving control structure is arranged on a storage bin, and the quantitative feeding structure is arranged at the lower end of the storage bin, one end of the quantitative feeding structure penetrates through the storage bin and is connected with the driving control structure;

the hierarchical screening mechanism includes: the device comprises a vertical frame, a primary screening structure, a secondary screening structure and a collecting hopper, wherein the vertical frame is arranged in a fixed frame and positioned below a storage bin, the primary screening structure is arranged on the vertical frame, the secondary screening structure is arranged on the vertical frame and positioned below the primary screening structure, and the collecting hopper is arranged below the secondary screening structure;

the wet material recycling mechanism comprises: the device comprises a guide chute, a recovery bin, a collecting chute, a rotary impact structure and a heating drying structure, wherein one end of the guide chute is connected with a secondary screening structure, the recovery bin is arranged at the lower end of the guide chute, the collecting chute is arranged at the lower part of the recovery bin, the rotary impact structure is arranged on the recovery bin, and the heating drying structure is arranged on the inner side wall surface of the recovery bin.

The drive control structure includes: the automatic feeding device comprises a mounting frame, a servo motor and a connecting shaft, wherein the mounting frame is arranged on a storage bin, the servo motor is arranged on the mounting frame, the driving end of the servo motor is vertically downward, and the connecting shaft is fixedly arranged at the driving end of the servo motor.

The quantitative feeding structure comprises: the feeding device comprises a feeding pipe, a feeding screw and a fixing shaft, wherein the feeding pipe is arranged at the lower end of a storage bin, the feeding screw is arranged in the feeding pipe, one end of the fixing shaft is connected with the feeding screw, and the other end of the fixing shaft is connected with a connecting shaft.

The primary screening structure comprises: the vibration motor is arranged at one end of the primary screen, one end of the primary screen is rotationally connected with the fixing frame, and the other end of the primary screen is connected with the two compression springs.

The secondary screening structure comprises: the device comprises a secondary screen, a driving motor and a deflection supporting component, wherein one end of the secondary screen is rotationally connected with a vertical frame, the driving motor is arranged on the side wall of a fixing frame, and the deflection supporting component is arranged on the side wall of the fixing frame and one end of the deflection supporting component is connected with the driving end of the driving motor.

The deflection support assembly includes: the support frame, pivot and two eccentric wheels, the support frame sets up on the mount lateral wall, the pivot rotates cartridge in the support frame, and one end is connected with driving motor's drive end, two the eccentric wheels respectively fixed suit in the pivot, and rim position and second grade screen cloth laminating mutually.

The rotary impact structure includes: support, rotation motor, impact coupling assembling and filter screen board, the support sets up on retrieving the storehouse, rotation motor sets up on the support, and the drive end is perpendicular downwards, impact coupling assembling's one end is connected with rotation motor's drive end, the other end stretches into retrieving in the storehouse, the filter screen board sets up in retrieving the storehouse, and is located impact coupling assembling below.

The impact connection assembly includes: the device comprises an impact shaft and a plurality of impact posts, wherein one end of the impact shaft is connected with the driving end of a rotary motor, the other end of the impact shaft stretches into a recycling bin, and the impact posts are annularly arranged at the lower end of the impact shaft and are attached to a filter screen plate.

The heat drying structure includes: the protection casing and a plurality of annular heating pipes, the protection casing sets up in retrieving the storehouse, a plurality of annular heating pipes set up respectively on retrieving the inside wall surface in storehouse, and be located the protection casing.

The first-stage screen and the second-stage screen are both provided with U-shaped surrounding baffles.

According to the mineral aggregate wet material automatic separation equipment manufactured by the technical scheme, the hierarchical screening mechanism is arranged at the lower part of the storage bin, the automatic discharging mechanism is arranged in the storage bin, the wet material recovery processing mechanism is arranged at one side of the hierarchical screening mechanism, aggregates to be processed are put into the storage bin, the aggregates in the storage bin are quantitatively conveyed through the automatic discharging mechanism, and are screened by the hierarchical screening mechanism, and massive wet materials enter the wet material recovery processing mechanism under the vibration effect to be dehumidified and dried, so that the resource utilization rate is improved, the structure is simple, the automation degree is high, and the problems that in the prior art, the separation of massive wet materials and aggregates is inconvenient, the wet materials after separation cannot be recovered, the processing production efficiency is affected, and the resource waste is caused are solved.

Drawings

Fig. 1 is a schematic diagram of a front view section structure of an automatic mineral aggregate wet material separating device according to the present invention.

Fig. 2 is a schematic top view of an automatic mineral aggregate wet material separating device according to the present invention.

Fig. 3 is a schematic diagram of a front view cross-section structure of an automatic discharging mechanism of an automatic mineral aggregate wet material separating device according to the present invention.

Fig. 4 is a schematic diagram of a partially enlarged front view of a classifying screening mechanism of an automatic mineral aggregate wet material separating device according to the present invention.

Fig. 5 is a schematic side view of the mineral aggregate wet material automatic separating device of fig. 4.

Fig. 6 is a schematic diagram of a front view cross-section structure of a wet material recycling mechanism of an automatic mineral aggregate wet material separating device according to the present invention.

In the figure: 1-a fixing frame; 2-a storage bin; 3-standing; 4-collecting hoppers; 5-a guide groove; 6, a recovery bin; 7-a material collecting groove; 8-mounting frames; 9-a servo motor; 10-connecting shafts; 11-a material guide pipe; 12-a feeding screw; 13-a fixed shaft; 14-connecting frames; 15-compressing a spring; 16-stage screen mesh; 17-a vibration motor; 18-a secondary screen; 19-a drive motor; 20-supporting frames; 21-a rotating shaft; 22-eccentric wheel; 23-a bracket; 24-rotating electric machine; 25-a filter screen plate; 26-an impact shaft; 27-an impact column; 28-protecting cover; 29-annular heating tube; 30-U type encloses fender.

Detailed Description

The present invention is specifically described below with reference to the accompanying drawings, as shown in fig. 1-6, all the electrical components in the present invention are connected with the power supply adapted thereto by wires by a person skilled in the art, and an appropriate controller should be selected according to the actual situation, so as to meet the control requirements, specific connection and control sequence, and in the following working principles, the sequential working sequence between the electrical components should be referred to complete the electrical connection, and the detailed connection means thereof are known in the art, and the following main description of the working principles and processes will not be provided for explaining the electrical control.

Examples: as can be seen from fig. 1-6 of the specification, the scheme comprises a fixing frame 1 and a bin 2, wherein the position relationship and the connection relationship are as follows, the bin 2 is arranged on the fixing frame 1, an automatic discharging mechanism is arranged in the bin 2, a grading type screening mechanism is arranged at the lower part of the bin 2, a wet material recovery processing mechanism is arranged at one side of the grading type screening mechanism, a grading type screening mechanism is arranged at the lower part of the bin 2, an automatic discharging mechanism is arranged in the bin 2, a wet material recovery processing mechanism is arranged at one side of the grading type screening mechanism, aggregate to be processed is put into the bin 2, the aggregate in the bin 2 is quantitatively conveyed through the automatic discharging mechanism, and is screened by the grading type screening mechanism, and block wet materials enter the wet material recovery processing mechanism under the vibration effect to be dehumidified and dried, so that the resource utilization rate is improved, the structure is simple, and the automation degree is high;

in a specific implementation process, the automatic discharging mechanism comprises: drive control structure and ration pay-off structure, drive control structure set up on feed bin 2, and ration pay-off structure sets up on the lower extreme of feed bin 2, and one end runs through in feed bin 2, and is connected with drive control structure, and wherein hierarchical screening mechanism includes: the setting of grudging post 3, one-level screening structure, second grade screening structure and collecting hopper 4, grudging post 3 set up in mount 1, and be located feed bin 2 below, and one-level screening structure sets up on grudging post 3, and second grade screening structure sets up on grudging post 3, and is located one-level screening structure below, and collecting hopper 4 sets up in the below of second grade screening structure, and above-mentioned wet material recovery processing mechanism includes: the material collecting device comprises a material guide groove 5, a recycling bin 6, a material collecting groove 7, a rotary impact structure and a heating and drying structure, wherein one end of the material guide groove 5 is connected with the secondary screening structure, the recycling bin 6 is arranged at the lower end of the material guide groove 5, the material collecting groove 7 is arranged at the lower part of the recycling bin 6, the rotary impact structure is arranged on the recycling bin 6, the heating and drying structure is arranged on the inner side wall surface of the recycling bin 6, when the material collecting device is used, the quantitative feeding structure is controlled and regulated through the driving control structure, so that raw materials in the material bin 2 are quantitatively led out, the led out materials enter the primary screening structure and the secondary screening structure for screening treatment, qualified aggregate enters the material collecting hopper 4, blocky wet materials enter the material guide groove 5 and further enter the recycling bin 6, and the wet materials are dried through the cooperation of the rotary impact structure and the heating and drying structure in the recycling bin 6, and the dried aggregate enters the material collecting groove 7.

As can be seen from fig. 1 to 3 of the specification, in the implementation process, the driving control structure includes: mounting bracket 8, servo motor 9 and connecting axle 10, mounting bracket 8 set up on feed bin 2, and servo motor 9 sets up on mounting bracket 8, and the drive end is perpendicular downwards, and connecting axle 10 sets firmly on servo motor 9 driving end, and wherein quantitative feeding structure includes: the feeding device comprises a feeding pipe 11, a feeding screw 12 and a fixed shaft 13, wherein the feeding pipe 11 is arranged at the lower end of a storage bin 2, the feeding screw 12 is arranged in the feeding pipe 11, one end of the fixed shaft 13 is connected with the feeding screw 12, the other end of the fixed shaft is connected with a connecting shaft 10, and when the feeding device is used, the fixed shaft 13 and the feeding screw 12 at the lower end of the connecting shaft 10 are driven to synchronously rotate by controlling the driving end of a servo motor 9 on a mounting frame 8 to continuously discharge raw materials in the storage bin 2 through the feeding pipe 11, and the discharge amount can be accurately controlled by controlling the rotation speed of the feeding screw 12.

As can be seen from fig. 1-2 of the specification and fig. 3-4, in the specific implementation process, the primary screening structure includes: link 14, two compression springs 15, one-level screen cloth 16 and vibrating motor 17, link 14 sets up on the grudging post 3 lateral wall, and two compression springs 15 set up respectively on link 14, and one end and mount 1 rotation of one-level screen cloth 16 are connected, and the other end is connected with two compression springs 15, and vibrating motor 17 sets up on one end of one-level screen cloth 16, and wherein second grade screening structure includes: second grade screen cloth 18, driving motor 19 and deflection supporting component, the one end and the grudging post 3 rotation of second grade screen cloth 18 are connected, and driving motor 19 sets up on mount 1 lateral wall, and deflection supporting component sets up on mount 1 lateral wall, and one end is connected with driving motor 19's drive end, and above-mentioned deflection supporting component includes: the support frame 20, pivot 21 and two eccentric wheels 22, the support frame 20 sets up on mount 1 lateral wall, pivot 21 rotates the cartridge in support frame 20, and one end is connected with driving motor 19's drive end, two eccentric wheels 22 are fixed the suit respectively in pivot 21, and rim position is laminated mutually with second grade screen cloth 18, when using, start vibrating motor 17, vibrating motor 17 drives first screen cloth and link 14, under compression spring 15's elasticity supporting effect, shake in step, thereby improve screening work efficiency, control start driving motor 19, driving motor 19's drive end rotates, and then drive support frame 20's pivot 21 rotates, thereby pivot 21 rotates the rim position of eccentric wheel 22 on making pivot 21 carries out the pushing action to the second screen cloth, thereby make the second screen cloth carry out even reciprocating type and vibrate, thereby improve screening work efficiency, cooperation and screen cloth use, can separate out most massive wet material.

As can be seen from fig. 1-2 of the specification and fig. 6, in the implementation process, the rotary impact structure includes: support 23, rotation motor 24, impact connection subassembly and filter screen plate 25, support 23 set up on retrieving storehouse 6, rotation motor 24 sets up on support 23, and the drive end is perpendicular downwards, and impact connection subassembly's one end is connected with rotation motor 24's drive end, the other end stretches into retrieving storehouse 6 in, and filter screen plate 25 sets up in retrieving storehouse 6, and is located impact connection subassembly below, and wherein impact connection subassembly includes: impact shaft 26 and a plurality of impact post 27, the one end of impact shaft 26 is connected with the drive end of rotary motor 24, and the other end stretches into retrieve in the storehouse 6, and a plurality of impact post 27 are located on the lower extreme of impact shaft 26, and laminate mutually with the filter screen plate 25, and above-mentioned heating and drying structure includes: the protection casing 28 and a plurality of ring heating pipe 29, protection casing 28 sets up in retrieving storehouse 6, a plurality of ring heating pipe 29 set up respectively on retrieving storehouse 6's inside wall face, and be located protection casing 28, when using, start the inboard ring heating pipe 29 of protection casing 28, heat the wet material in retrieving storehouse 6, and make the moisture after the heating follow retrieve storehouse 6 upper portion discharge, and then dry the cubic wet material, rotary motor 24 on the support 23 is started simultaneously, control rotary motor 24's drive end rotates, and then drive impact shaft 26 rotates, impact shaft 26 rotates and then drives impact post 27 and impact crushing to cubic wet material, the acceleration is handled the process, the aggregate after the stoving crushing is through filter screen 25, enter into in the collecting hopper 4.

In a specific implementation process, the U-shaped enclosure 30 is arranged on the first-stage screen 16 and the second-stage screen 18, so that materials are prevented from scattering, and the operation stability is further improved.

To sum up, this mineral aggregate wet material autosegregation equipment, set up hierarchical screening mechanism in feed bin 2 lower part, be provided with automatic bin discharge mechanism in feed bin 2, one side of hierarchical screening mechanism is provided with wet material recovery processing mechanism, throw into the feed bin 2 with the aggregate that treats, carry out quantitative transport to the aggregate in the feed bin 2 through automatic bin discharge mechanism, and utilize hierarchical screening mechanism to sieve the aggregate, cubic wet material enters into wet material recovery processing mechanism under the vibrations effect, dehumidify dry processing, improve resource utilization, and a structure is simple, degree of automation is high, among the prior art, ordinary vibrations screening equipment is inconvenient for carrying out the separation of cubic wet material and aggregate, and wet material after the separation can't retrieve, influence machining production efficiency, cause the problem of wasting of resources simultaneously.

The above technical solution only represents the preferred technical solution of the present invention, and some changes that may be made by those skilled in the art to some parts of the technical solution represent the principles of the present invention, and the technical solution falls within the scope of the present invention.

Claims (1)

1. The mineral aggregate wet material automatic separation equipment comprises a fixed frame (1) and a bin (2), and is characterized in that the bin (2) is arranged on the fixed frame (1), an automatic discharging mechanism is arranged in the bin (2), a grading type screening mechanism is arranged at the lower part of the bin (2), and a wet material recycling mechanism is arranged at one side of the grading type screening mechanism;

the automatic discharging mechanism comprises: the quantitative feeding device comprises a driving control structure and a quantitative feeding structure, wherein the driving control structure is arranged on a storage bin (2), the quantitative feeding structure is arranged at the lower end of the storage bin (2), and one end of the quantitative feeding structure penetrates through the storage bin (2) and is connected with the driving control structure;

the hierarchical screening mechanism includes: the device comprises a vertical frame (3), a primary screening structure, a secondary screening structure and a collecting hopper (4), wherein the vertical frame (3) is arranged in a fixed frame (1) and is positioned below a storage bin (2), the primary screening structure is arranged on the vertical frame (3), the secondary screening structure is arranged on the vertical frame (3) and is positioned below the primary screening structure, and the collecting hopper (4) is arranged below the secondary screening structure;

the wet material recycling mechanism comprises: the device comprises a guide chute (5), a recovery bin (6), a material collecting tank (7), a rotary impact structure and a heating and drying structure, wherein one end of the guide chute (5) is connected with a secondary screening structure, the recovery bin (6) is arranged at the lower end of the guide chute (5), the material collecting tank (7) is arranged at the lower part of the recovery bin (6), the rotary impact structure is arranged on the recovery bin (6), and the heating and drying structure is arranged on the inner side wall surface of the recovery bin (6);

the drive control structure includes: the automatic feeding device comprises a mounting frame (8), a servo motor (9) and a connecting shaft (10), wherein the mounting frame (8) is arranged on a storage bin (2), the servo motor (9) is arranged on the mounting frame (8) and the driving end is vertically downward, and the connecting shaft (10) is fixedly arranged at the driving end of the servo motor (9);

the quantitative feeding structure comprises: the feeding device comprises a feeding pipe (11), a feeding screw (12) and a fixed shaft (13), wherein the feeding pipe (11) is arranged at the lower end of a storage bin (2), the feeding screw (12) is arranged in the feeding pipe (11), one end of the fixed shaft (13) is connected with the feeding screw (12), and the other end of the fixed shaft is connected with a connecting shaft (10);

the primary screening structure comprises: the vibration screen comprises a connecting frame (14), two compression springs (15), a first-stage screen (16) and a vibration motor (17), wherein the connecting frame (14) is arranged on the side wall of the vertical frame (3), the two compression springs (15) are respectively arranged on the connecting frame (14), one end of the first-stage screen (16) is rotationally connected with a fixing frame (1), the other end of the first-stage screen is connected with the two compression springs (15), and the vibration motor (17) is arranged on one end of the first-stage screen (16);

the secondary screening structure comprises: the device comprises a secondary screen (18), a driving motor (19) and a deflection supporting component, wherein one end of the secondary screen (18) is rotationally connected with a vertical frame (3), the driving motor (19) is arranged on the side wall of a fixed frame (1), and the deflection supporting component is arranged on the side wall of the fixed frame (1) and one end of the deflection supporting component is connected with the driving end of the driving motor (19);

the deflection support assembly includes: the device comprises a supporting frame (20), a rotating shaft (21) and two eccentric wheels (22), wherein the supporting frame (20) is arranged on the side wall of a fixed frame (1), the rotating shaft (21) is rotatably inserted into the supporting frame (20), one end of the rotating shaft is connected with the driving end of a driving motor (19), the two eccentric wheels (22) are respectively fixedly sleeved on the rotating shaft (21), and the rim positions of the two eccentric wheels are attached to a secondary screen (18);

the rotary impact structure includes: the device comprises a bracket (23), a rotary motor (24), an impact connecting assembly and a filter screen plate (25), wherein the bracket (23) is arranged on a recycling bin (6), the rotary motor (24) is arranged on the bracket (23) and the driving end is vertically downward, one end of the impact connecting assembly is connected with the driving end of the rotary motor (24), the other end of the impact connecting assembly stretches into the recycling bin (6), and the filter screen plate (25) is arranged in the recycling bin (6) and is positioned below the impact connecting assembly;

the impact connection assembly includes: the device comprises an impact shaft (26) and a plurality of impact columns (27), wherein one end of the impact shaft (26) is connected with the driving end of a rotary motor (24), the other end of the impact shaft extends into a recycling bin (6), and the impact columns (27) are annularly arranged at the lower end of the impact shaft (26) and are attached to a filter screen plate (25);

the heat drying structure includes: the protection cover (28) and a plurality of annular heating pipes (29), wherein the protection cover (28) is arranged in the recovery bin (6), and the annular heating pipes (29) are respectively arranged on the inner side wall surface of the recovery bin (6) and are positioned in the protection cover (28);

the primary screen (16) and the secondary screen (18) are both provided with U-shaped enclosing baffles (30).

Images