CN114308657A

CN114308657A - A gravity screening ore sand device for in aspect of building

Info

Publication number: CN114308657A
Application number: CN202210142231.0A
Authority: CN
Inventors: 方高林
Original assignee: Shenzhen Bohua Decoration Co ltd
Current assignee: Shenzhen Bohua Decoration Co ltd
Priority date: 2022-02-16
Filing date: 2022-02-16
Publication date: 2022-04-12

Abstract

The invention relates to a gravity screening ore sand device, in particular to a gravity screening ore sand device for construction. The gravity screening ore device for the building is convenient for people to screen the iron ore, high in working efficiency and not easy to accumulate. The utility model provides a gravity screening ore sand device for in aspect of building, is including separation box, supporting baseplate and start button, and separation box bottom rigid coupling has supporting baseplate, and separation box leading flank left lower part rigid coupling has start button. According to the invention, a proper amount of material is poured onto the slotted belt assembly from the left side opening of the separation box body repeatedly to drive the servo motor to work, so that the slotted belt assembly drives the material to move rightwards, the air pump enables the diversion conduit to start blowing air through the air inlet pipe, the material moves rightwards to be above the diversion conduit, and the diversion conduit blows ore sand to the upper part in the separation box body, so that people can conveniently screen iron ore sand, and the working efficiency is high.

Description

A gravity screening ore sand device for in aspect of building

Technical Field

The invention relates to a gravity screening ore sand device, in particular to a gravity screening ore sand device for construction.

Background

Iron ore sand can often be used in the aspect of the building, generally can filter the ore sand in advance, present iron ore screening ore sand, generally let iron ore sand fall from the eminence, ann magnetic coil at the intermediate position, change the whereabouts direction of iron ore with magnetism, also be exactly for a speed of magnet ore sand, give an external force of iron-bearing ore sand again in the vertical direction, let iron-bearing and non-iron-bearing ore sand separate, accomplish the ore dressing, so operation is very troublesome, and highly can not infinitely increase, and pile up together easily iron ore, it is very difficult to follow-up screening ore sand, work efficiency is low.

Therefore, the gravity sand screening device for the building, which is convenient for people to screen iron sand, has high working efficiency and is not easy to accumulate, is needed to be designed so as to solve the prior art problem.

Disclosure of Invention

In order to overcome the defects that the operation is very troublesome, iron ores are easy to accumulate together, the subsequent screening of ore sand is very difficult, and the working efficiency is low in the prior art, the invention has the technical problems that: the gravity ore screening device for the building is convenient for people to screen iron ore, high in working efficiency and not easy to accumulate.

The technical implementation scheme of the invention is as follows: the utility model provides a gravity screening ore sand device for in aspect of building, including the separation box, supporting baseplate, the start button, stop button, the air pump, the intake pipe, the reposition of redundant personnel pipe, the dust cover, airtight dustcoat, fortune material mechanism and stock stop, separation bottom of the case portion rigid coupling has supporting baseplate, separation box leading flank left lower part rigid coupling has start button, separation box leading flank left lower part rigid coupling has stop button, stop button is located the start button right side, separation box outer trailing flank right lower part rigid coupling has the air pump, air pump downside gas outlet is connected with the intake pipe, the intake pipe front end is connected with the reposition of redundant personnel pipe, air pump upside air inlet cover is equipped with and is used for dirt-proof dust cover, reposition of redundant personnel pipe rear end cover is equipped with airtight dustcoat, be equipped with the fortune material mechanism that is used for carrying on the separation box, still be equipped with the stock stop that is used for connecing the material on the separation box.

Further, fortune material mechanism is including servo motor, the drive shaft, fluting belt assembly, driven rotating shaft, unloading swash plate and a photoelectric sensor, the outside leading flank right side lower part rigid coupling of separator box has servo motor, the right part lower side rotation formula of separator box is equipped with the drive shaft, drive shaft front end and servo motor's output shaft fixed connection, the left part lower side rotation formula of separator box is equipped with driven rotating shaft, be connected with fluting belt assembly between driven rotating shaft middle part and the drive shaft middle part, the right part lower side of separator box is equipped with the unloading swash plate that is used for the unloading, the internal top left side rigid coupling of separator box has a photoelectric sensor.

Further, the stock stop includes fixed frame, location cross axle and airtight open close plate, and separation box medial surface upper portion rigid coupling has fixed frame, and the interval rotary type is equipped with many location cross axles on the fixed frame, and location cross axle middle part rigid coupling has the airtight open close plate that is used for connecing the material, airtight open close plate and fixed frame sliding connection.

Further, the device also comprises a material distributing mechanism, the material distributing mechanism comprises a closed bottom frame, a fixed side frame, a water storage tank, a first transmission assembly, a driven transverse shaft, a material distributing belt assembly, a discharging box, a booster pump, a slotted material scraping rod, a rotary spray pipe, a discharging inclined plate, a driving gear, an electromagnetic block module and a second photoelectric sensor, the right upper part of the inner back side of the separating box is fixedly connected with the fixed side frame, the inner side of the fixed side frame is fixedly connected with the closed bottom frame, the right side of the outer top of the separating box is fixedly connected with the water storage tank, the upper part of the separating box is symmetrically and rotatably provided with the driven transverse shaft, the first transmission assembly is connected between the rear part of the right driven transverse shaft and the rear part of the driving shaft, the rotary type material distributing belt assembly is connected between the middle parts of the driven transverse shafts on the left side and the right side, the upper part of the outer right side of the separating box is fixedly connected with a material discharging box for collection, the booster pump is arranged on the right rear side of the water storage tank, the slotted material scraping rod for discharging is arranged on the upper side of the right side of the separating box, the inside rotatory spray tube that is equipped with of material pole is scraped in the fluting, and rotatory spray tube rotates with the booster pump to be connected, and separation box right part upside is equipped with ejection of compact swash plate, and the anterior rigid coupling of right-hand driven cross axle has drive gear, and drive gear can drive the fluting and scrape the material pole and rotate, and the inboard upper portion rigid coupling of separation box has the electromagnetic block module, and the inboard right side rigid coupling of top has second photoelectric sensor in the separation box.

Further, the automatic material turning device comprises a material turning mechanism, wherein the material turning mechanism comprises a positioning roller, a driving rack, a first limiting slide block, a limiting vertical rod, a material turning middle shaft, a driven gear, a fixed cross rod, a first limiting roller, a positioning inclined block, a first reset guide rod, a first reset spring, a fixed vertical rod, a material turning frame, a second reset spring, a boosting roller and a third reset spring, a plurality of positioning rollers are arranged on the grooved belt assembly at intervals, the lower side of the front part in the closed bottom frame is fixedly connected with the first reset guide rod in a bilateral symmetry manner, the first limiting slide block is arranged on the first reset guide rod in a sliding manner, the first reset spring is wound on the first reset guide rod, one end of the first reset spring is connected with the first limiting slide block, the other end of the first reset spring is connected with the closed bottom frame, the fixed cross rod is fixedly connected between the first limiting slide blocks on the left side and the right side, the driving rack is arranged on the fixed cross rod in a sliding manner, the inside and fixed horizontal pole left part of drive rack is connected with the wraparound has third reset spring, the symmetrical rotary type is equipped with first spacing gyro wheel around the drive rack right part, drive rack bottom left side rigid coupling has spacing pole setting, spacing pole setting and positioning roller cooperation, airtight underframe middle part rotary type is equipped with the stirring axis, stirring axis front portion rigid coupling has driven gear, driven gear and drive gear cooperation, separation box anterior right middle side rigid coupling has the location sloping block, the location sloping block cooperates with first spacing gyro wheel, stirring axis front and back both sides all cross-under have fixed pole setting, the longitudinal symmetry slidingtype is equipped with the stirring frame that is used for stirring between the fixed pole setting of front and back both sides, the rigid coupling has second reset spring between stirring frame inner and the fixed pole setting inside, second reset spring quantity is four, the stirring frame outside rotary type is equipped with helps the moving gyro wheel.

Further comprises a floating mechanism, the floating mechanism comprises a second limiting roller, a positioning side block, an arched positioning rod and a connecting straight rod, the second limiting slide block, the second resets the guide arm, fourth reset spring and material smearing grid plate, drive rack trailing flank right part rotary type and be equipped with the spacing gyro wheel of second, lower part interval is equipped with four second guide arms that reset in the airtight underframe, the gliding type is equipped with the spacing slider of second on the second guide arm that resets, around there being fourth reset spring on the second guide arm that resets, fourth reset spring one end and the spacing slider of second, the fourth reset spring other end is connected with airtight underframe, the spacing slider medial surface rigid coupling of second has the location side piece, the rigid coupling has the arch locating lever between two location side piece medial surface lower parts in the place ahead, the rigid coupling has the connection straight-bar between two location side piece medial surface lower parts in the rear, the rigid coupling has the material smearing grid plate that is used for the tiling between the both sides location side piece lower part in the front and back.

The feeding mechanism comprises a second transmission assembly, a charging box, a limiting transverse shaft and a material shifting roller, the charging box is fixedly connected to the left side of the outer top of the separation box body, the limiting transverse shaft is rotatably arranged at the lower portion of the charging box, the material shifting roller used for feeding is fixedly connected to the middle of the limiting transverse shaft, and the second transmission assembly is connected between the front portion of the limiting transverse shaft and the front portion of the driven rotating shaft.

The gravity ore sand screening device for the building is characterized by further comprising an electric cabinet, wherein the electric cabinet is arranged on the lower left side of the front part of the separation box body, a switching power supply, a power supply module and a control module are arranged in the electric cabinet, the switching power supply supplies power for the gravity ore sand screening device for the building, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the starting button, the stopping button, the first photoelectric sensor and the second photoelectric sensor are electrically connected with the control module, and the servo motor, the booster pump, the air pump and the electromagnetic block module are connected with the control module through a peripheral circuit.

The invention has the beneficial effects that:

1. according to the invention, a proper amount of material is poured onto the slotted belt assembly from the left side opening of the separation box body repeatedly to drive the servo motor to work, so that the slotted belt assembly drives the material to move rightwards, the air pump enables the diversion conduit to start blowing air through the air inlet pipe, the material moves rightwards to be above the diversion conduit, and the diversion conduit blows ore sand to the upper part in the separation box body, so that people can conveniently screen iron ore sand, and the working efficiency is high.

2. Under the action of the material turning mechanism, the fixed upright posts are turned reversely to drive the material turning frame to turn reversely, and the material turning frame turns over materials in a reverse mode, so that the materials can be prevented from being stacked together.

3. Under the action of the feeding mechanism, the material poking roller rotates forwards to poke the material into the slotted belt assembly, so that people can conveniently carry out feeding.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a schematic view of a first partially-separated body structure of the material conveying mechanism of the invention.

Fig. 6 is a schematic diagram of a second partially-separated body structure of the material conveying mechanism of the invention.

Fig. 7 is a partial perspective view of the stock stop of the present invention.

Fig. 8 is a perspective view of a third embodiment of the present invention.

Fig. 9 is a schematic view of a first partial body structure of the material distribution mechanism of the present invention.

Fig. 10 is a schematic view of a second partial body structure of the distributing mechanism of the present invention.

Fig. 11 is a schematic perspective view of a third part of the distributing mechanism of the present invention.

Fig. 12 is a schematic perspective view of a fourth part of the material separating mechanism of the present invention.

Fig. 13 is a schematic view of a first partially separated body structure of the stirring mechanism of the invention.

Fig. 14 is a schematic view of a second partially separated body structure of the stirring mechanism of the invention.

Fig. 15 is a perspective view of a third part of the stirring mechanism of the invention.

Fig. 16 is a schematic perspective view of a fourth part of the stirring mechanism of the invention.

Fig. 17 is a schematic view of a first partially-separated body structure of the troweling mechanism of the present invention.

Fig. 18 is a schematic view of a second partial body structure of the troweling mechanism of the present invention.

Fig. 19 is a schematic perspective view of a part of the feeding mechanism of the present invention.

FIG. 20 is a block circuit diagram of the present invention.

Fig. 21 is a schematic circuit diagram of the present invention.

Reference numerals: 1_ separation box, 2_ support base plate, 3_ electric cabinet, 31_ start button, 32_ stop button, 4_ air pump, 5_ air inlet pipe, 6_ shunt pipe, 61_ dust cover, 62_ closed outer cover, 7_ material conveying mechanism, 71_ servo motor, 72_ drive shaft, 73_ grooved belt assembly, 74_ driven rotating shaft, 75_ blanking inclined plate, 76_ first photoelectric sensor, 8_ material stopping mechanism, 81_ fixed outer frame, 82_ positioning horizontal shaft, 83_ closed split plate, 9_ material separating mechanism, 91_ closed bottom frame, 92_ fixed side frame, 93_ water storage tank, 94_ first drive assembly, 95_ driven horizontal shaft, 96_ material separating belt assembly, 97_ blanking box, 98_ booster pump, 99_ grooved material scraping rod, 910_ rotary nozzle, 911_ discharge material, inclined plate 912_ drive gear, 913_ electromagnetic block module, 914_ second photoelectric sensor, 10_ material turning mechanism, 101_ positioning roller, 102_ driving rack, 103_ first limiting slider, 104_ limiting vertical rod, 105_ material turning central shaft, 106_ driven gear, 107_ fixed cross rod, 108_ first limiting roller, 109_ positioning inclined block, 1010_ first resetting guide rod, 1011_ first resetting spring, 1012_ fixed vertical rod, 1013_ material turning frame, 1014_ second resetting spring, 1015_ assisting roller, 1016_ third resetting spring, 11_ leveling mechanism, 111_ second limiting roller, 112_ positioning side block, 113_ arched positioning rod, 114_ connecting straight rod, 115_ second limiting slider, 116_ second resetting guide rod, 117_ fourth resetting spring, 118_ material wiping grid plate, 12_ feeding mechanism, 121_ second transmission assembly, 122_ charging box, 123_ limiting transverse shaft and 124_ material turning roller.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

A gravity screening ore sand device for building comprises a separation box body 1, a supporting bottom plate 2, a starting button 31, a stopping button 32, an air pump 4, an air inlet pipe 5, a diversion conduit 6, a dust cover 61, a closed outer cover 62, a material conveying mechanism 7 and a material stopping mechanism 8, wherein the bottom of the separation box body 1 is fixedly connected with the supporting bottom plate 2, the left lower part of the front side surface of the separation box body 1 is fixedly connected with the starting button 31, the left lower part of the front side surface of the separation box body 1 is fixedly connected with the stopping button 32, the stopping button 32 is positioned at the right side of the starting button 31, the right lower part of the outer rear side surface of the separation box body 1 is fixedly connected with the air pump 4, the air outlet at the lower side of the air pump 4 is connected with the air inlet pipe 5, the front end of the air inlet pipe 5 is connected with the diversion conduit 6, the dust cover 61 is sleeved at the upper side of the air pump 4, the rear end of the diversion conduit 6 is sleeved with the closed outer cover 62, the material conveying mechanism 7 is arranged on the separation box body 1, the material conveying mechanism 7 can convey materials, the separating box body 1 is further provided with a material blocking mechanism 8, and after ore sand is screened, the material blocking mechanism 8 can block the screened ore sand.

The material conveying mechanism 7 comprises a servo motor 71, a driving shaft 72, a slotted belt component 73, a driven rotating shaft 74, a blanking sloping plate 75 and a first photoelectric sensor 76, the servo motor 71 is fixedly connected to the right lower part of the outer front side surface of the separation box body 1, the driving shaft 72 is rotatably arranged on the right lower part of the separation box body 1, the front end of the driving shaft 72 is fixedly connected with an output shaft of the servo motor 71, the driven rotating shaft 74 is rotatably arranged on the left lower part of the separation box body 1, the slotted belt component 73 is connected between the middle part of the driven rotating shaft 74 and the middle part of the driving shaft 72, the slotted belt component 73 is composed of two belt pulleys and a belt, one belt pulley is arranged in the middle part of the driven rotating shaft 74, the other belt pulley is arranged in the middle part of the driving shaft 72, the belt is wound between the two belt pulleys, the blanking sloping plate 75 is arranged on the right lower part of the separation box body 1, and residual ores or sundries can fall into a collection container through the blanking sloping plate 75, a first photoelectric sensor 76 is fixedly connected to the left side of the inner top of the separation box body 1.

The material blocking mechanism 8 comprises a fixed outer frame 81, a positioning cross shaft 82 and a closed opening plate 83, the fixed outer frame 81 is fixedly connected to the upper portion of the inner side face of the separation box body 1, a plurality of positioning cross shafts 82 are rotatably arranged on the fixed outer frame 81 at intervals, the closed opening plate 83 is fixedly connected to the middle portion of each positioning cross shaft 82, after the ore sand is screened out, the closed opening plate 83 can block the ore sand to avoid backflow, and the closed opening plate 83 is slidably connected with the fixed outer frame 81.

People press a power supply main switch to electrify the device, firstly, an operator places a collecting container under a blanking inclined plate 75, presses a start button 31 once, the start button 31 sends a signal, a control module receives the signal and then controls a servo motor 71 to work, the servo motor 71 drives a driving shaft 72 to rotate forwards, the driving shaft 72 rotates forwards and is matched with a driven rotating shaft 74 to drive a slotted belt component 73 to rotate forwards, then a proper amount of material is poured onto the slotted belt component 73 from a left port of a separation box body 1 repeatedly, the slotted belt component 73 drives the material to move rightwards, a first photoelectric sensor 76 detects the material to pass through, the first photoelectric sensor 76 sends a signal, the control module receives the signal and then controls an air pump 4 to work, the air pump 4 starts to blow air through an air inlet pipe 5, so that the material moves rightwards to be above a shunt pipe 6, and the shunt pipe 6 also blows ore sand in the material upwards, meanwhile, the closed open-close plate 83 swings upwards to be in an inclined state, ore sand is continuously turned over at the upper part in the separation box body 1, the slotted belt component 73 continuously rotates forwards to drive the residual impurities to move rightwards, the residual impurities move rightwards and fall into the collection container through the blanking inclined plate 75, after all ore sand is screened, the stop button 32 is pressed once, the stop button 32 sends a signal, the control module receives the signal and controls the servo motor 71 to stop, the driving shaft 72 stops matching with the driven rotating shaft 74 to drive the slotted belt component 73 to rotate forwards, the first photoelectric sensor 76 does not detect the passing of the material any more, the first photoelectric sensor 76 sends a signal, the control module receives the signal and controls the air pump 4 to stop, under the action of gravity, the closed open-close plate 83 swings downwards to reset, the ore sand falls and is accumulated on the closed open-close plate 83, and the collection container is taken up to carry out subsequent treatment on the impurities, and then collecting the ore sand on the closed plywood 83 for subsequent treatment.

Example 2

On the basis of embodiment 1, as shown in fig. 8-18, the separating device further includes a separating mechanism 9, the separating mechanism 9 includes a closed bottom frame 91, a fixed side frame 92, a water storage tank 93, a first transmission assembly 94, a driven horizontal shaft 95, a separating belt assembly 96, a blanking box 97, a booster pump 98, a slotted scraper bar 99, a rotary nozzle 910, a discharge inclined plate 911, a driving gear 912, an electromagnetic block module 913 and a second photoelectric sensor 914, the fixed side frame 92 is fixedly connected to the upper right portion of the rear side surface in the separating box 1, the closed bottom frame 91 is fixedly connected to the inner side of the fixed side frame 92, the water storage tank 93 is fixedly connected to the right side of the outer top of the separating box 1, the driven horizontal shaft 95 is arranged on the upper portion of the separating box 1 in a left-right symmetrical manner, a first transmission assembly 94 is connected between the rear portion of the right driven horizontal shaft 95 and the rear portion of the driving shaft 72, the first transmission assembly 94 is composed of two belt pulleys and a belt pulley, one belt pulley is installed on the rear portion of the driving shaft 72, the other belt pulley is arranged at the rear part of the right driven transverse shaft 95, the belt is wound between the two belt pulleys, a material distribution belt assembly 96 is connected between the middle parts of the left and right driven transverse shafts 95, the material distribution belt assembly 96 consists of two belt pulleys and a belt, the belt pulleys are arranged at the middle parts of the driven transverse shafts 95, the belt is wound between the two belt pulleys, a blanking box 97 is fixedly connected to the upper part of the outer right side surface of the separation box body 1, a booster pump 98 is arranged at the rear side of the right part of the water storage tank 93, a slotted scraping rod 99 is rotatably arranged at the upper side of the right part of the separation box body 1, the slotted scraping rod 99 can pull ore sand on the material distribution belt assembly 96 down, a rotary spray pipe 910 is arranged inside the slotted scraping rod 99, the rotary spray pipe 910 is rotatably connected with the booster pump 98, a discharge inclined plate 911 is arranged at the upper side of the right part of the separation box body 1, a drive gear 912 is fixedly connected to the front part of the right driven transverse shaft 95, an electromagnetic block module 913 is fixedly connected to the upper portion of the inner side of the separation box body 1, and a second photoelectric sensor 914 is fixedly connected to the right side of the top of the separation box body 1.

The automatic material turning device further comprises a material turning mechanism 10, wherein the material turning mechanism 10 comprises a positioning roller 101, a driving rack 102, a first limiting slide block 103, a limiting vertical rod 104, a material turning central shaft 105, a driven gear 106, a fixed cross rod 107, a first limiting roller 108, a positioning inclined block 109, a first reset guide rod 1010, a first reset spring 1011, a fixed vertical rod 1012, a material turning frame 1013, a second reset spring 1014, a boosting roller 1015 and a third reset spring 1016, a plurality of positioning rollers 101 are arranged on the slotted belt assembly 73 at intervals, the first reset guide rod 1010 is symmetrically and fixedly connected to the left and right of the lower side of the front part in the closed bottom frame 91, the first limiting slide block 103 is slidably arranged on the first reset guide rod 1010, the first reset spring 1011 is wound on the first reset guide rod 1010, one end of the first reset spring 1011 is connected with the first limiting slide block 103, the other end of the first reset spring 1011 is connected with the closed bottom frame 91, the fixed cross rod 107 is fixedly connected between the first limiting slide blocks 103 on the left side and the right side, a driving rack 102 is arranged on the fixed cross bar 107 in a sliding manner, a third return spring 1016 is wound between the inside of the driving rack 102 and the left part of the fixed cross bar 107, a first limit roller 108 is symmetrically arranged at the right part of the driving rack 102 in a front-back rotating manner, a limit upright 104 is fixedly connected at the left side of the bottom of the driving rack 102, the limit upright 104 is matched with the positioning roller 101, a material turning middle shaft 105 is rotatably arranged at the middle part of the closed bottom frame 91, a driven gear 106 is fixedly connected at the front part of the material turning middle shaft 105, the driven gear 106 is matched with a driving gear 912, a positioning inclined block 109 is fixedly connected at the right middle side of the front part of the separating box body 1, the positioning inclined block 109 is matched with the first limit roller 108, fixed upright 1012 are connected at the front side and the back side of the material turning middle shaft 105 in a penetrating manner, material turning frames 1013 are symmetrically arranged between the front fixed upright 1012 at the front side and the back side, the material frames 1013 at the upper and the lower side can turn over the material frames 1013 to avoid stacking, a second return spring 1014 is fixedly connected between the inner end of the material turning frame 1012, the number of the second return springs 1014 is four, and the outer side of the material turnover frame 1013 is rotatably provided with an assistant roller 1015.

The trowelling device comprises a trowelling mechanism 11, the trowelling mechanism 11 comprises a second limiting roller 111, a positioning side block 112, an arch positioning rod 113, a connecting straight rod 114, a second limiting sliding block 115, a second reset guide rod 116, a fourth reset spring 117 and a trowelling grid plate 118, the second limiting roller 111 is rotatably arranged on the right portion of the rear side face of a driving rack 102, four second reset guide rods 116 are arranged at intervals at the lower portion inside a closed bottom frame 91, the second reset guide rod 116 is slidably provided with the second limiting sliding block 115, the fourth reset spring 117 is wound on the second reset guide rod 116, one end of the fourth reset spring 117 is connected with the second limiting sliding block 115, the other end of the fourth reset spring 117 is connected with the closed bottom frame 91, the positioning side block 112 is fixedly connected to the inner side face of the second limiting sliding block 115, the arch positioning rod 113 is fixedly connected between the lower portions of the inner side faces of the two positioning side blocks 112 in front, the connecting straight rod 114 is fixedly connected between the inner side faces of the two positioning side blocks 112 in rear, a material smearing grid plate 118 is fixedly connected between the lower parts of the front and rear side positioning side blocks 112, and the material smearing grid plate 118 can realize the purpose of flatly spreading materials and is convenient to screen.

Firstly, an operator adds a proper amount of clear water into the water storage tank 93, when the start button 31 is pressed once, the start button 31 sends a signal, the control module receives the signal and then controls the servo motor 71 and the electromagnetic block module 913 to work, the slotted belt module 73 rotates forwards to drive the material to move rightwards, when the material moves rightwards to be above the shunt conduit 6, the air pump 4 enables the shunt conduit 6 to start blowing through the air inlet pipe 5, ore sand is blown to the split belt module 96, the electromagnetic block module operates to enable the ore sand to be adsorbed on the split belt module 913, so that the drive shaft 72 rotates forwards to drive the first drive assembly 94 to rotate forwards, the first drive assembly 94 rotates forwards to drive the right driven cross shaft 95 to rotate forwards, the left driven cross shaft 95 and the right driven cross shaft 95 rotate forwards to drive the split belt module 96 to rotate forwards, the split belt module 96 rotates forwards to drive the ore sand to rotate forwards, the second photoelectric sensor 914 detects the ore sand to pass, the second photoelectric sensor 914 sends out a signal, the control module controls the operation of the booster pump 98 after receiving the signal, the booster pump 98 discharges clear water into the rotary spray pipe 910, the rotary spray pipe 910 moistens the slotted scraper bar 99 for scraping, meanwhile, the right driven transverse shaft 95 positively rotates to drive the driving gear 912 positively rotates, the driving gear 912 positively rotates to drive the slotted scraper bar 99 negatively rotates, the slotted scraper bar 99 negatively rotates to pull down ore sand, the ore sand drops into the blanking box 97 through the discharging inclined plate 911, after all ore sand screening is completed, the stop button 32 is pressed once, the stop button 32 sends out a signal, the control module controls the servo motor 71 and the electromagnetic block module 913 to stop after receiving the signal, the driving shaft 72 stops rotating, the first transmission assembly 94 no longer drives the right driven transverse shaft 95 positively rotates, the distributing belt assembly 96 stops positively rotating, the second photoelectric sensor 914 no longer detects the ore sand passing, the second photoelectric sensor 914 sends a signal, the control module receives the signal and then controls the booster pump 98 to stop, and the blanking box 97 is opened to perform subsequent treatment on the ore sand, so that the ore sand can be conveniently collected.

When the servo motor 71 works, the slotted belt component 73 rotates forwards to drive the positioning roller 101 to rotate forwards, the positioning roller 101 rotates forwards to contact with the limiting upright stanchion 104, the positioning roller 101 enables the limiting upright stanchion 104 to move rightwards, the limiting upright stanchion 104 moves rightwards to drive the driving rack 102 to move rightwards, the third return spring 1016 is stretched, the driving rack 102 moves rightwards to drive the driven gear 106 to rotate backwards, the driven gear 106 rotates backwards to drive the turning middle shaft 105 to rotate backwards, the turning middle shaft 105 rotates backwards to drive the fixed upright stanchion 1012 to rotate backwards, the fixed upright 1012 rotates backwards to drive the turning frame 1013 to rotate backwards, the turning frame 1013 rotates backwards to drive the assisting roller 1015 rotates backwards to turn over the material, the second return spring 1014 plays a buffering role, the driving rack 102 moves rightwards to drive the first limiting roller 108 to move rightwards, the first limiting roller 108 moves rightwards to contact with the positioning inclined block 109, and the positioning inclined block 109 enables the first limiting roller 108 to move downwards for a certain distance, first reset spring 1011 is compressed, first spacing gyro wheel 108 moves down and drives drive rack 102 downstream, drive rack 102 downstream breaks away from with driven gear 106, because of the effect of third reset spring 1016, drive rack 102 drives spacing pole setting 104 and moves left and reset, and first spacing gyro wheel 108 also breaks away from with location sloping block 109, because of the effect of first reset spring 1011, drive rack 102 drives first spacing gyro wheel 108 rebound and resets, so, can avoid the material to pile up together.

When the servo motor 71 works, the driving rack 102 moves rightwards to drive the second limiting roller 111 to move rightwards, when the second limiting roller 111 moves rightwards to the convex part of the arched positioning rod 113, the second limiting roller 111 drives the arched positioning rod 113 to move downwards, the arched positioning rod 113 moves downwards to drive the positioning side block 112 to move downwards, the fourth return spring 117 is compressed, the connecting straight rod 114 enables the positioning side blocks 112 on the left side and the right side to move synchronously, the positioning side block 112 moves downwards to drive the material smearing grid plate 118 to move downwards, so that the positioning inclined block 109 enables the first limiting roller 108 to move downwards, the first return spring 1011 is compressed, the first limiting roller 108 moves downwards to drive the driving rack 102 to move downwards, the driving rack 102 moves downwards to drive the second limiting roller 111 to move downwards continuously, the positioning side block 112 drives the material smearing grid plate 118 to move downwards continuously, and the first return spring 1011 is compressed continuously, the material smearing grid plate 118 moves downwards to be in contact with the materials to smear the materials, the driving rack 102 drives the second limiting idler wheel 111 to move leftwards to be reset to the concave position of the arch-shaped positioning rod 113 under the action of the third reset spring 1016, and the positioning side block 112 drives the material smearing grid plate 118 to move upwards under the action of the first reset spring 1011, so that the materials can be tiled, and ore sand screening is facilitated.

Example 3

On the basis of the embodiment 1 and the embodiment 2, as shown in fig. 2 and fig. 19, the separating box further comprises a feeding mechanism 12, the feeding mechanism 12 comprises a second transmission assembly 121, a charging box 122, a limiting transverse shaft 123 and a material shifting roller 124, the charging box 122 is fixedly connected to the left side of the outer top of the separating box body 1, the limiting transverse shaft 123 is rotatably arranged at the lower part of the charging box 122, the material shifting roller 124 is fixedly connected to the middle part of the limiting transverse shaft 123, the material shifting roller 124 can realize the feeding of the material, the second transmission assembly 121 is connected between the front part of the limiting transverse shaft 123 and the front part of the driven rotating shaft 74, the second transmission assembly 121 comprises two pulleys and a belt, one pulley is mounted at the front part of the limiting transverse shaft 123, the other pulley is mounted at the front part of the driven rotating shaft 74, and the belt is wound between the two pulleys.

Firstly, an operator pours a proper amount of materials into the charging box 122, the materials are in contact with the material stirring roller 124, when the servo motor 71 works, the driven rotating shaft 74 rotates positively to drive the second transmission assembly 121 to rotate positively, the second transmission assembly 121 rotates positively to drive the limiting transverse shaft 123 to rotate positively, the limiting transverse shaft 123 rotates positively to drive the material stirring roller 124 to rotate positively, the material stirring roller 124 rotates positively to stir the materials into the slotted belt assembly 73, after all ore sand screening is completed, the driven rotating shaft 74 stops driving the limiting transverse shaft 123 to rotate positively through the second transmission assembly 121, and the material stirring roller 124 also stops rotating positively, so that people can conveniently feed the materials.

As shown in fig. 2, 20 and 21, the gravity screening device for the building also comprises an electric cabinet 3, wherein the electric cabinet 3 is arranged at the lower left side of the front part of the separation box body 1, a switching power supply, a power supply module and a control module are arranged in the electric cabinet 3, the switching power supply supplies power to the gravity screening device for the building, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the start button 31, the stop button 32, the first photoelectric sensor 76 and the second photoelectric sensor 914 are all electrically connected with the control module, and the servo motor 71, the booster pump 98, the air pump 4 and the electromagnetic block module 913 are all connected with the control module through peripheral circuits.

It should be understood that this example is only for illustrating the present invention and is not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.

Claims

1. A gravity screening ore sand device for building is characterized by comprising a separation box body (1), a supporting base plate (2), a starting button (31), a stopping button (32), an air pump (4), an air inlet pipe (5), a diversion conduit (6), a dust cover (61), a closed outer cover (62), a material conveying mechanism (7) and a material stopping mechanism (8), wherein the bottom of the separation box body (1) is fixedly connected with the supporting base plate (2), the left lower part of the front side surface of the separation box body (1) is fixedly connected with the starting button (31), the left lower part of the front side surface of the separation box body (1) is fixedly connected with the stopping button (32), the stopping button (32) is positioned on the right side of the starting button (31), the right lower part of the outer rear side surface of the separation box body (1) is fixedly connected with the air inlet pipe (4), an air outlet at the lower side of the air pump (4) is connected with the air inlet pipe (5), the front end of the air inlet pipe (5) is connected with the diversion conduit (6), an air inlet at the upper side of the air pump (4) is sleeved with a dustproof dust cover (61), the rear end of the shunt pipe (6) is sleeved with a closed outer cover (62), a material conveying mechanism (7) for conveying is arranged on the separation box body (1), and a material stopping mechanism (8) for receiving materials is further arranged on the separation box body (1).

2. A gravity screening sand apparatus for architectural applications as defined in claim 1 wherein the conveyor means (7) includes a servo motor (71), a drive shaft (72), and a slotted belt assembly (73), driven rotating shaft (74), unloading swash plate (75) and first photoelectric sensor (76), the outer leading flank right lower part rigid coupling of separator box (1) has servo motor (71), the rotation of separator box (1) right part lower side is equipped with drive shaft (72), the output shaft fixed connection of drive shaft (72) front end and servo motor (71), the rotation of separator box (1) left part lower side is equipped with driven rotating shaft (74), be connected with fluting belt assembly (73) between driven rotating shaft (74) middle part and drive shaft (72) middle part, separator box (1) right part lower side is equipped with unloading swash plate (75) that are used for the unloading, top left side rigid coupling has first photoelectric sensor (76) in separator box (1).

3. The gravity screening ore sand device for the building aspect as claimed in claim 2, wherein the material blocking mechanism (8) comprises a fixed outer frame (81), a positioning cross shaft (82) and a closed open-close plate (83), the fixed outer frame (81) is fixedly connected to the upper portion of the inner side surface of the separation box body (1), a plurality of positioning cross shafts (82) are rotatably arranged on the fixed outer frame (81) at intervals, the closed open-close plate (83) for receiving materials is fixedly connected to the middle portion of the positioning cross shaft (82), and the closed open-close plate (83) is slidably connected with the fixed outer frame (81).

4. The gravity screening ore sand device for the building aspect according to claim 3, characterized in that the gravity screening ore sand device further comprises a material distributing mechanism (9), the material distributing mechanism (9) comprises a closed bottom frame (91), a fixed side frame (92), a water storage tank (93), a first transmission component (94), a driven transverse shaft (95), a material distributing belt component (96), a blanking box (97), a booster pump (98), a slotted scraping rod (99), a rotary spray pipe (910), a discharging inclined plate (911), a driving gear (912), an electromagnetic block module (913) and a second photoelectric sensor (914), the fixed side frame (92) is fixedly connected to the upper right portion of the inner rear side surface of the separation box body (1), the closed bottom frame (91) is fixedly connected to the inner side of the fixed side frame (92), the water storage tank (93) is fixedly connected to the right side of the outer top of the separation box body (1), the driven transverse shaft (95) is rotatably arranged on the upper portion of the separation box body (1) in a left-right symmetry mode, a first transmission assembly (94) is connected between the rear part of a right driven transverse shaft (95) and the rear part of a driving shaft (72), a material distribution belt assembly (96) is connected between the middle parts of the left and right driven transverse shafts (95), a blanking box (97) for collection is fixedly connected to the upper part of the outer right side surface of the separation box body (1), a booster pump (98) is arranged on the rear side of the right part of the water storage box (93), a slotted scraping rod (99) for blanking is rotatably arranged on the upper side of the right part of the separation box body (1), a rotary spray pipe (910) is arranged inside the slotted scraping rod (99), the rotary spray pipe (910) is rotatably connected with the booster pump (98), a discharge inclined plate (911) is arranged on the upper side of the right part of the separation box body (1), a driving gear (912) is fixedly connected to the front part of the right driven transverse shaft (95), the driving gear (912) can drive the slotted scraping rod (99) to rotate, an electromagnetic block module (913) is fixedly connected to the upper part of the inner side of the separation box body (1), a second photoelectric sensor (914) is fixedly connected to the right side of the inner top of the separation box body (1).

5. The gravity ore sand screening device for the building aspect according to claim 4, characterized by further comprising a material turning mechanism (10), wherein the material turning mechanism (10) comprises a positioning roller (101), a driving rack (102), a first limiting slide block (103), a limiting upright rod (104), a material turning middle shaft (105), a driven gear (106), a fixed cross rod (107), a first limiting roller (108), a positioning inclined block (109), a first reset guide rod (1010), a first reset spring (1011), a fixed upright rod (1012), a material turning frame (1013), a second reset spring (1014), an auxiliary roller (1015) and a third reset spring (1016), a plurality of positioning rollers (101) are arranged on the slotted belt assembly (73) at intervals, the first reset guide rod (1010) is fixedly connected to the left and right sides of the lower side of the front part in the closed bottom frame (91) symmetrically, and the first limiting slide block (103) is arranged on the first reset guide rod (1010) in a sliding manner, a first reset spring (1011) is wound on the first reset guide rod (1010), one end of the first reset spring (1011) is connected with a first limit slider (103), the other end of the first reset spring (1011) is connected with the closed bottom frame (91), a fixed cross rod (107) is fixedly connected between the first limit sliders (103) on the left side and the right side, a driving rack (102) is arranged on the fixed cross rod (107) in a sliding mode, a third reset spring (1016) is wound between the inside of the driving rack (102) and the left part of the fixed cross rod (107), a first limit roller (108) is symmetrically and rotatably arranged on the right part of the driving rack (102) in a front-and-back rotating mode, a limit upright rod (104) is fixedly connected on the left side of the bottom of the driving rack (102), the limit upright rod (104) is matched with a positioning roller (101), a material turning middle shaft (105) is rotatably arranged on the middle part of the closed bottom frame (91), a driven gear (106) is fixedly connected on the front part of the material turning middle shaft (105), the driven gear (106) is matched with the driving gear (912), a positioning inclined block (109) is fixedly connected to the right middle side of the front portion of the separating box body (1), the positioning inclined block (109) is matched with the first limiting roller (108), the front side and the rear side of the material turning middle shaft (105) are respectively provided with a fixed vertical rod (1012) in a penetrating mode, a material turning frame (1013) used for turning is arranged between the fixed vertical rods (1012) on the front side and the rear side in a vertically symmetrical sliding mode, a second return spring (1014) is fixedly connected between the inner end of the material turning frame (1013) and the inside of the fixed vertical rod (1012), the number of the second return springs (1014) is four, and the auxiliary roller (1015) is rotatably arranged on the outer side of the material turning frame (1013).

6. The gravity screening ore sand device for the construction aspect according to claim 5, characterized in that the device further comprises a trowelling mechanism (11), the trowelling mechanism (11) comprises a second limiting roller (111), a positioning side block (112), an arched positioning rod (113), a connecting straight rod (114), a second limiting slide block (115), a second reset guide rod (116), a fourth reset spring (117) and a trowelling grid plate (118), the second limiting roller (111) is rotatably arranged at the right part of the rear side surface of the driving rack (102), four second reset guide rods (116) are arranged at intervals at the lower part in the closed bottom frame (91), the second limiting slide block (115) is slidably arranged on the second reset guide rod (116), the fourth reset spring (117) is wound on the second reset guide rod (116), one end of the fourth reset spring (117) is connected with the second limiting slide block (115), and the other end of the fourth reset spring (117) is connected with the closed bottom frame (91), the inner side of the second limiting sliding block (115) is fixedly connected with a positioning side block (112), an arch-shaped positioning rod (113) is fixedly connected between the lower parts of the inner sides of the front two positioning side blocks (112), a connecting straight rod (114) is fixedly connected between the lower parts of the inner sides of the rear two positioning side blocks (112), and a material smearing grid plate (118) which is used for tiling is fixedly connected between the lower parts of the front and rear two positioning side blocks (112).

7. The gravity ore sand screening device for the construction aspect according to the claim 6, characterized in that the device further comprises a feeding mechanism (12), the feeding mechanism (12) comprises a second transmission component (121), a charging box (122), a limiting transverse shaft (123) and a material shifting roller (124), the charging box (122) is fixedly connected to the left side of the outer top of the separation box body (1), the limiting transverse shaft (123) is rotatably arranged at the lower part of the charging box (122), the material shifting roller (124) for feeding is fixedly connected to the middle part of the limiting transverse shaft (123), and the second transmission component (121) is connected between the front part of the limiting transverse shaft (123) and the front part of the driven rotating shaft (74).

8. The gravity ore sand screening device for the building aspect according to claim 7, characterized by further comprising an electric cabinet (3), wherein the electric cabinet (3) is installed at the lower left side of the front part of the separation box body (1), a switching power supply, a power supply module and a control module are included in the electric cabinet (3), the switching power supply supplies power to the gravity ore sand screening device for the building aspect, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the starting button (31), the stopping button (32), the first photoelectric sensor (76) and the second photoelectric sensor (914) are electrically connected with the control module, and the servo motor (71), the booster pump (98), the air pump (4) and the electromagnetic block module (913) are connected with the control module through a peripheral circuit.