CN111546493A

CN111546493A - Agitated vessel is smashed to high-efficient single power for building

Info

Publication number: CN111546493A
Application number: CN202010458692.XA
Authority: CN
Inventors: 高元琴
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-27
Filing date: 2020-05-27
Publication date: 2020-08-18

Abstract

The invention discloses a high-efficiency single-power crushing and stirring device for buildings, which comprises a base, a fixing frame and a processing bin, wherein the fixing frame is arranged on the base, the processing bin is arranged on the fixing frame, the upper part of the processing bin is rectangular, the lower part of the processing bin is cylindrical, a discharge door is arranged on the side wall of the processing bin, a crushing and stirring mechanism is arranged in the processing bin, and a single-power output mechanism is arranged on the base. The control system has high integration degree, simple structure and high reliability.

Description

Agitated vessel is smashed to high-efficient single power for building

Technical Field

The invention relates to the technical field of constructional engineering, in particular to high-efficiency single-power crushing and stirring equipment for buildings.

Background

The building engineering refers to an engineering entity formed by the construction of various building constructions and their auxiliary facilities and the installation activities of lines, pipelines and equipment matched with the building constructions, wherein the building constructions refer to the engineering which has a top cover, a beam column, a wall, a foundation and can form an internal space and meet the requirements of people on production, living, study and public activities, the building materials can be divided into structural materials, decorative materials and some special materials, and the structural materials comprise wood, bamboo, stone, cement, concrete, metal, brick and tile, ceramics, glass, engineering plastics, composite materials and the like; the decorative material comprises various coatings, paints, plating layers, veneers, ceramic tiles with various colors, glass with special effects and the like; the special material is used for water proofing, moisture proofing, corrosion prevention, fire prevention, flame retardance, sound insulation, heat preservation, sealing and the like.

The raw material crushing and mixing device for the construction engineering is used for fully mixing the raw materials such as sand, gravel, cement and the like in the aspect of the construction engineering, and some devices for crushing the raw materials with larger volume can be used for the construction of constructional engineering, solve the problems of low efficiency, difficult crushing work and insufficient mixing of the traditional manual mixing, has important significance for the construction of constructional engineering, but the prior raw material crushing and mixing device for constructional engineering has more complex structure and higher energy consumption, and simultaneously has some problems in the aspect of environmental pollution during working, that is, when the device is used for crushing and mixing raw materials, the generated dust can be scattered from the position of the feed inlet and directly discharged into the air to cause environmental pollution, meanwhile, the device has certain harm to workers, and the scheme is generated by the intensive research aiming at the problems.

Disclosure of Invention

The invention aims to solve the problems, designs high-efficiency single-power crushing and stirring equipment for buildings, and solves the problems that the existing raw material crushing and mixing device for building engineering is relatively complex in structure and high in energy consumption, and has some environmental pollution problems in work, namely, when the device is used for crushing and mixing raw materials, generated dust can be scattered from a position of a feed inlet and directly discharged into air, so that the environment pollution is caused, and meanwhile, the harm is caused to working personnel.

The technical scheme of the invention for realizing the aim is as follows: a high-efficiency single-power crushing and stirring device for buildings comprises a base, a fixing frame and a processing bin, wherein the fixing frame is arranged on the base, the processing bin is arranged on the fixing frame, the upper part of the processing bin is rectangular, the lower part of the processing bin is cylindrical, a discharge door is arranged on the side wall of the processing bin, a crushing and stirring mechanism is arranged in the processing bin, a single-power output mechanism is arranged on the base and connected with the crushing and stirring mechanism, an auxiliary feeding mechanism is arranged on one side of the processing bin, and a centrifugal dust settling mechanism is arranged above the processing bin;

smash rabbling mechanism includes: a counter-grinding type crushing structure and a rotary stirring structure;

the opposite-grinding type crushing structure is arranged in the processing bin, the rotary stirring structure is arranged in the processing bin, and the rotary stirring structure is positioned below the opposite-grinding type crushing structure;

the single power output mechanism includes: the crushing device comprises a driving motor, a speed reducer, an output shaft, a crushing transmission structure and a stirring transmission structure;

the driving motor is arranged on the base, the speed reducer is arranged on the base, the input end of the speed reducer is connected with the driving end of the driving motor, the output shaft is arranged on the output end of the speed reducer, the crushing transmission structure is arranged on the counter-grinding type crushing structure and is connected with the output shaft, and the stirring transmission structure is arranged on the lower end of the rotary stirring structure and is connected with the output shaft;

centrifugal dust fall mechanism includes: a lifting adjusting structure and a centrifugal dust removing structure;

the lifting adjusting structure is arranged on the fixing frame and is positioned at the upper end position of the processing bin, and the centrifugal dust removing structure is arranged at the lower end of the lifting adjusting structure.

The crushing structure of the counter-grinding type comprises: the device comprises a material guide groove, two rotating shafts and two grinding rollers;

the baffle box install in on the processing storehouse upper end open position, two the equal activity cartridge of axis of rotation in the processing storehouse, and two the one end of axis of rotation all run through in the processing storehouse lateral wall, stretch out outside the processing storehouse, two the roller is all installed in the blending bunker, and two the equal fixed mounting of roller is in two axes of rotation, and two leave and be equipped with the certain clearance between the roller.

The rotary stirring structure comprises: the limiting frame, the stirring shaft and the stirring paddle;

the spacing is installed in the processing storehouse, just the spacing is located to rolling formula shredding structure below, the stirring shaft is installed in the processing storehouse, the upper end activity cartridge of (mixing) shaft in on the spacing, the lower extreme of (mixing) shaft run through in terminal surface under the processing storehouse, the (mixing) shaft with the lower terminal surface rotation of spacing and processing storehouse is connected, the stirring rake install in the processing storehouse, just the fixed suit of stirring rake is in on the (mixing) shaft.

The crushing transmission structure comprises: the box body, a first driven gear, a second driven gear, a first guide gear, a second guide gear, a power transmission assembly and a transmission chain;

the box body is arranged on the side wall of the processing bin and sleeved on one exposed side of the two rotating shafts, the first driven gear and the second driven gear are respectively fixedly sleeved on the exposed ends of the two rotating shafts, two ends of the first guide gear are rotationally connected with the side wall of the box body, the first guide gear is arranged above the second driven gear, the two ends of the second guide gear are rotationally connected with the side wall of the box body, the second guide gear is arranged below the second driven gear, the power transmission component is arranged on one side of the second driven gear, and one end of the power transmission assembly is connected with the output shaft, and the transmission chain is meshed with the power transmission assembly, the first guide gear, the first driven gear, the second guide gear, the second driven gear and the power transmission assembly in sequence.

The power transmission assembly includes: the transmission mechanism comprises a transmission shaft, a transmission gear, a power gear, a driving gear and a driving chain;

the transmission shaft is movably arranged in the box body, the transmission gear is fixedly sleeved on the transmission shaft and meshed with the transmission chain, the power gear is fixedly sleeved on the output shaft, the driving gear is fixedly sleeved on the transmission shaft, and the driving chain is meshed with the power gear and the driving gear.

The stirring transmission structure comprises: the box body, a first bevel gear, a connecting shaft, a second bevel gear, a third bevel gear and a fourth bevel gear;

the box install in on the terminal surface under the processing storehouse, the box install in processing storehouse below, the (mixing) shaft and the output shaft all stretches into in the box, fixed suit of first bevel gear is in one of output shaft is served, the connecting shaft is installed in the box, the fixed suit of second bevel gear in on the lower extreme of (mixing) shaft, the fixed suit of third bevel gear in the one end of connecting shaft, just the third bevel gear with first bevel gear meshes mutually, the fixed suit of fourth bevel gear in on the other end of connecting shaft, just the fourth bevel gear with the second bevel gear meshes mutually.

The lift adjustment structure includes: the dust collecting device comprises a support frame, a first hydraulic cylinder, four telescopic columns and a dust collecting cover;

the support frame is arranged on the fixing frame, the first hydraulic cylinder is arranged on the support frame along the vertical direction, the four telescopic columns are arranged at the lower end of the support frame respectively and are positioned at the four corners of the first hydraulic cylinder respectively, the dust hood is arranged at the movable end of the first hydraulic cylinder and is connected with the four telescopic columns.

The centrifugal dust removal structure comprises: the device comprises a dust removal box, an induced draft pipe, a cloth bag dust removal net and a centrifugal fan;

the dust removal case install in on the mount, induced duct one end with the dust removal case is connected, the other end of induced duct with the dust cage is linked together, the sack removes dust the net install in the dust removal incasement, centrifugal fan installs dust removal case one side, centrifugal fan's air inlet end with the dust removal case is linked together.

The supplementary mechanism of adding material includes: the device comprises a conveyor, a feeding groove and an auxiliary water injection structure;

the conveyer install in on the mount, add the silo and install in the row of conveyer is served, add the one end of silo and stretch into in the processing storehouse, supplementary water injection structure install in on the mount, supplementary water injection structure's one end with the processing storehouse is linked together.

The supplementary water injection structure includes: a water tank, a water supply pump, a water supply pipe and an electromagnetic flow valve;

the water tank is arranged on the fixing frame, the water supply pump is arranged on the water tank, the water inlet end of the water supply pump is communicated with the water tank, one end of the water supply pipe is communicated with the water outlet end of the water supply pump, the other end of the water supply pipe is communicated with the processing bin, and the electromagnetic flow valve is fixedly sleeved on the water supply pipe.

The high-efficiency single-power crushing and stirring equipment for the building, which is manufactured by the technical scheme of the invention, is characterized in that a crushing and stirring mechanism is arranged in a processing bin, various raw materials are put into the processing bin by matching with an auxiliary feeding mechanism, the crushing and stirring mechanism is controlled by a single-power output mechanism arranged on a base, the raw materials put into the processing bin are efficiently crushed and stirred, meanwhile, a centrifugal dust falling mechanism is arranged at a feeding port, the dust generated in the crushing and stirring process is prevented from being scattered from the feeding port, the control system has high integration degree, simple structure and high reliability, the problems of complex structure, high energy consumption and environmental pollution in the work of the existing raw material crushing and mixing device for the building engineering are solved, namely, when the device is used for crushing and mixing the raw materials, the dust that produces can follow the position effluvium of feed inlet, directly discharges in the air, causes the pollution of environment, has the problem of harm to the staff simultaneously.

Drawings

FIG. 1 is a schematic structural view of a high-efficiency single-power crushing and stirring device for buildings according to the present invention.

FIG. 2 is a schematic sectional structure view of the A-A position of the high-efficiency single-power crushing and stirring equipment for buildings.

Fig. 3 is a schematic top view of the high-efficiency single-power crushing and stirring device for buildings according to the invention.

FIG. 4 is a schematic sectional structure view of the position B-B of the high-efficiency single-power crushing and stirring equipment for buildings.

FIG. 5 is a schematic cross-sectional view of the position C-C of the high-efficiency single-power crushing and stirring device for buildings according to the invention.

FIG. 6 is a schematic sectional view of a high-efficiency single-power crushing and stirring device for construction.

Fig. 7 is a schematic structural view of a crushing transmission structure of the high-efficiency single-power crushing and stirring equipment for buildings in a front view.

Fig. 8 is a partially enlarged structural schematic diagram of fig. 3 of the high-efficiency single-power crushing and stirring device for buildings according to the invention.

Fig. 9 is a partially enlarged structural schematic view of a centrifugal dust settling mechanism of the high-efficiency single-power crushing and stirring equipment for buildings.

Fig. 10 is a schematic top sectional view of a stirring transmission structure of the high-efficiency single-power crushing and stirring equipment for buildings according to the invention.

In the figure: 1-a base; 2-a fixing frame; 3-processing a bin; 4-a discharge gate; 5-driving a motor; 6-a speed reducer; 7-an output shaft; 8-a material guide groove; 9-a rotating shaft; 10-a grinding roller; 11-a limiting frame; 12-a stirring shaft; 13-a stirring paddle; 14-a cartridge; 15-a first driven gear; 16-a second driven gear; 17-a first guide gear; 18-a second guide gear; 19-a drive chain; 20-a drive shaft; 21-a transmission gear; 22-a power gear; 23-a drive gear; 24-a drive chain; 25-a box body; 26-a first bevel gear; 27-a connecting shaft; 28-a second bevel gear; 29-three bevel gears; 30-a fourth bevel gear; 31-a support frame; 32-a first hydraulic cylinder; 33-telescopic column; 34-a dust collection cover; 35-a dust removal box; 36-induced duct; 37-cloth bag dust removal net; 38-centrifugal fan; 39-a conveyor; 40-a feeding trough; 41-a water tank; 42-water supply pump; 43-water supply pipe; 44-electromagnetic flow valve.

Detailed Description

The invention is described in detail below with reference to the accompanying drawings, and as shown in fig. 1 to 10, an efficient single-power pulverizing and stirring apparatus for buildings includes a base 1, a fixing frame 2 and a processing bin 3, the fixing frame 2 is installed on the base 1, the processing bin 3 is installed on the fixing frame 2, the upper portion of the processing bin 3 is rectangular, the lower portion of the processing bin 3 is cylindrical, a discharge door 4 is arranged on the sidewall of the processing bin 3, a pulverizing and stirring mechanism is arranged in the processing bin 3, a single-power output mechanism is arranged on the base 1, the single-power output mechanism is connected with the pulverizing and stirring mechanism, an auxiliary material adding mechanism is arranged on one side of the processing bin 3, a centrifugal dust-settling mechanism is arranged above the processing bin 3, and the pulverizing and stirring mechanism includes: the crushing device comprises a counter-rolling type crushing structure and a rotary stirring structure, wherein the counter-rolling type crushing structure is arranged in the processing bin 3, the rotary stirring structure is arranged in the processing bin 3, and the rotary stirring structure is positioned below the counter-rolling type crushing structure; the single power output mechanism includes: the crushing device comprises a driving motor 5, a speed reducer 6, an output shaft 7, a crushing transmission structure and a stirring transmission structure, wherein the driving motor 5 is arranged on the base 1, the speed reducer 6 is arranged on the base 1, the input end of the speed reducer 6 is connected with the driving end of the driving motor 5, the output shaft 7 is arranged on the output end of the speed reducer 6, the crushing transmission structure is arranged on the opposite-grinding type crushing structure and is connected with the output shaft 7, and the stirring transmission structure is arranged on the lower end of the rotary stirring structure and is connected with the output shaft 7; centrifugal dust fall mechanism includes: the lifting adjusting structure is arranged on the fixed frame 2 and is positioned at the upper end of the processing bin 3, and the centrifugal dust removing structure is arranged at the lower end of the lifting adjusting structure; the crushing structure of the counter-grinding type comprises: a material guide chute 8, two rotating shafts 9 and two grinding rollers 10; the guide chute 8 is arranged at an opening position at the upper end of the processing bin 3, the two rotating shafts 9 are movably inserted into the processing bin 3, one ends of the two rotating shafts 9 penetrate through the side wall of the processing bin 3 and extend out of the processing bin 3, the two grinding rollers 10 are arranged in the mixing bin, the two grinding rollers 10 are fixedly arranged on the two rotating shafts 9, and a certain gap is reserved between the two grinding rollers 10; the rotary stirring structure comprises: the grinding device comprises a limiting frame 11, a stirring shaft 12 and a stirring paddle 13, wherein the limiting frame 11 is arranged in the processing bin 3, the limiting frame 11 is positioned below the opposite-grinding type crushing structure, the stirring shaft 12 is arranged in the processing bin 3, the upper end of the stirring shaft 12 is movably inserted in the limiting frame 11, the lower end of the stirring shaft 12 penetrates through the lower end face of the processing bin 3, the stirring shaft 12 is rotatably connected with the limiting frame 11 and the lower end face of the processing bin 3, the stirring paddle 13 is arranged in the processing bin 3, and the stirring paddle 13 is fixedly sleeved on the stirring shaft 12; the crushing transmission structure comprises: the processing bin comprises a box body 14, a first driven gear 15, a second driven gear 16, a first guide gear 17, a second guide gear 18, a power transmission assembly and a transmission chain 19, wherein the box body 14 is arranged on the side wall of the processing bin 3, the box body 14 is sleeved on the exposed side of the two rotating shafts 9, the first driven gear 15 and the second driven gear 16 are fixedly sleeved on the exposed ends of the two rotating shafts 9 respectively, two ends of the first guide gear 17 are rotatably connected with the side wall of the box body 14, the first guide gear 17 is arranged above the second driven gear 16, two ends of the second guide gear 18 are rotatably connected with the side wall of the box body 14, the second guide gear 18 is arranged below the second driven gear 16, the power transmission assembly is arranged on one side of the second driven gear 16, and one end of the power transmission assembly is connected with the output shaft 7, the drive chain 19 meshes in proper order power transmission assembly, first leading gear 17, first driven gear 15, second leading gear 18, second driven gear 16 and power transmission assembly, power transmission assembly includes: the transmission shaft 20 is movably arranged in the box body 14, the transmission gear 21 is fixedly sleeved on the transmission shaft 20, the transmission gear 21 is meshed with the transmission chain 19, the power gear 22 is fixedly sleeved on the output shaft 7, the driving gear 23 is fixedly sleeved on the transmission shaft 20, and the driving chain 24 is meshed with the power gear 22 and the driving gear 23; the stirring transmission structure comprises: a box body 25, a first bevel gear 26, a connecting shaft 27, a second bevel gear 28, a third bevel gear 29 and a fourth bevel gear 30, the box body 25 is arranged on the lower end surface of the processing bin 3, the box body 25 is arranged below the processing bin 3, the stirring shaft 12 and the output shaft 7 both extend into the box body 25, the first bevel gear 26 is fixedly sleeved on one end of the output shaft 7, the connecting shaft 27 is arranged in the box body 25, the second bevel gear 28 is fixedly sleeved on the lower end of the stirring shaft 12, the third bevel gear 29 is fixedly sleeved at one end of the connecting shaft 27, the third bevel gear 29 is engaged with the first bevel gear 26, the fourth bevel gear 30 is fixedly sleeved on the other end of the connecting shaft 27, and the fourth bevel gear 30 is meshed with the second bevel gear 28; the lift adjustment structure includes: the dust collection device comprises a support frame 31, a first hydraulic cylinder 32, four telescopic columns 33 and a dust collection cover 34, wherein the support frame 31 is arranged on the fixed frame 2, the first hydraulic cylinder 32 is arranged on the support frame 31 along the vertical direction, the four telescopic columns 33 are respectively arranged on the lower end of the support frame 31, the four telescopic columns 33 are respectively positioned at four corners of the first hydraulic cylinder 32, the dust collection cover 34 is arranged on the movable end of the first hydraulic cylinder 32, and the dust collection cover 34 is connected with the four telescopic columns 33; the centrifugal dust removal structure comprises: a dust removal box 35, an induced draft tube 36, a cloth bag dust removal net 37 and a centrifugal fan 38; the dust removal box 35 is arranged on the fixed frame 2, one end of the induced air pipe 36 is connected with the dust removal box 35, the other end of the induced air pipe 36 is communicated with the dust collection cover 34, the cloth bag dust removal net 37 is arranged in the dust removal box 35, the centrifugal fan 38 is arranged on one side of the dust removal box 35, and the air inlet end of the centrifugal fan 38 is communicated with the dust removal box 35; the supplementary mechanism of adding material includes: a conveyor 39, a feeding groove 40 and an auxiliary water injection structure; the conveyor 39 is arranged on the fixed frame 2, the feeding groove 40 is arranged on the discharging end of the conveyor 39, one end of the feeding groove 40 extends into the processing bin 3, the auxiliary water injection structure is arranged on the fixed frame 2, and one end of the auxiliary water injection structure is communicated with the processing bin 3; the supplementary water injection structure includes: a water tank 41, a water supply pump 42, a water supply pipe 43, and an electromagnetic flow valve 44; the water tank 41 is installed on the fixing frame 2, the water supply pump 42 is installed on the water tank 41, a water inlet end of the water supply pump 42 is communicated with the water tank 41, one end of the water supply pipe 43 is communicated with a water outlet end of the water supply pump 42, the other end of the water supply pipe 43 is communicated with the processing bin 3, and the electromagnetic flow valve 44 is fixedly sleeved on the water supply pipe 43.

The characteristics of this embodiment do, including base 1, mount 2 and processing storehouse 3, mount 2 is installed on base 1, processing storehouse 3 is installed on mount 2, the upper portion of processing storehouse 3 is the rectangle, the lower part is the cylinder type, be provided with baiting door 4 on the 3 lateral walls in processing storehouse, be provided with crushing rabbling mechanism in the processing storehouse 3, be provided with single power output mechanism on the base 1, single power output mechanism is connected with crushing rabbling mechanism, 3 one side in processing storehouse is provided with supplementary feeding mechanism, 3 tops in processing storehouse are provided with centrifugal dust fall mechanism, crushing rabbling mechanism includes: the device comprises a counter-rolling type crushing structure and a rotary stirring structure, wherein the counter-rolling type crushing structure is arranged in a processing bin 3, the rotary stirring structure is arranged in the processing bin 3, and the rotary stirring structure is positioned below the counter-rolling type crushing structure; the single power output mechanism includes: the crushing device comprises a driving motor 5, a speed reducer 6, an output shaft 7, a crushing transmission structure and a stirring transmission structure, wherein the driving motor 5 is arranged on a base 1, the speed reducer 6 is arranged on the base 1, the input end of the speed reducer 6 is connected with the driving end of the driving motor 5, the output shaft 7 is arranged on the output end of the speed reducer 6, the crushing transmission structure is arranged on a counter-rolling type crushing structure and is connected with the output shaft 7, and the stirring transmission structure is arranged on the lower end of a rotary stirring structure and is connected with the output shaft 7; centrifugal dust fall mechanism includes: the lifting adjusting structure is arranged on the fixed frame 2 and is positioned at the upper end of the processing bin 3, and the centrifugal dust removing structure is arranged at the lower end of the lifting adjusting structure; the high-efficiency single-power crushing and stirring equipment for the building is characterized in that a crushing and stirring mechanism is arranged in a processing bin 3, various raw materials are put into the processing bin 3 by matching with an auxiliary feeding mechanism, the crushing and stirring mechanism is controlled by utilizing a single-power output mechanism arranged on a base 1, the raw materials put into the processing bin 3 are efficiently crushed and stirred, a centrifugal dust falling mechanism is arranged at a feed port, the dust generated in the crushing and stirring process is prevented from being scattered out of the feed port, a control system is high in integration degree, simple in structure and high in reliability, the problems that the existing raw material crushing and mixing device for the building engineering is complex in structure and high in energy consumption, and meanwhile, some problems in the aspect of environmental pollution exist in the working process are solved, namely, when the device is used for crushing and mixing the raw materials, the generated dust can be scattered out of the feed port and directly discharged into the air, causing environmental pollution and harming the working personnel.

All the electrical components in the present application are connected with the power supply adapted to the electrical components through the wires, and an appropriate controller should be selected according to actual conditions to meet the control requirements, and specific connection and control sequences should be obtained.

Example (b): as can be known from fig. 1-10 of the specification, this scheme includes base 1, mount 2 and processing storehouse 3, its positional relationship and connection relation are as follows, mount 2 is installed on base 1, processing storehouse 3 is installed on mount 2, the upper portion of processing storehouse 3 is the rectangle, the lower part is the cylinder type, be provided with discharge door 4 on 3 lateral walls of processing storehouse, be provided with crushing rabbling mechanism in the processing storehouse 3, be provided with single power output mechanism on the base 1, single power output mechanism is connected with crushing rabbling mechanism, 3 one side of processing storehouse is provided with supplementary feeding mechanism, 3 tops in processing storehouse are provided with centrifugal dust fall mechanism, above-mentioned crushing rabbling mechanism includes: to rolling formula crushing structure and rotation stirring structure, its positional relationship and relation of connection are as follows, to rolling formula crushing structure and installing in silo 3, and rotation stirring structure is installed in silo 3, and rotation stirring structure is located to rolling formula crushing structure below, and above-mentioned single power take off mechanism includes: driving motor 5, reduction gear 6, output shaft 7, smash transmission structure and stirring transmission structure, its position relation and relation of connection are as follows, driving motor 5 installs on base 1, reduction gear 6 installs on base 1, and reduction gear 6's input is connected with driving motor 5 drive end, output shaft 7 installs on reduction gear 6's output, smash transmission structure and install on grinding formula crushing structure, and be connected with output shaft 7, stirring transmission structure installs on rotation stirring structure lower extreme, and be connected with output shaft 7, above-mentioned centrifugal dust fall mechanism includes: lifting adjusting structure and centrifugal dust removal structure, its position relation and relation of connection are as follows, lifting adjusting structure installs on mount 2, and be located processing storehouse 3 upper end position, centrifugal dust removal structure installs on lifting adjusting structure's lower extreme, in concrete implementation process, set up crushing rabbling mechanism in processing storehouse 3, the cooperation is supplementary to be added the material mechanism and to drop into all kinds of raw materials in processing storehouse 3, the single power take off mechanism who utilizes the setting on the base 1 controls crushing rabbling mechanism, carry out high-efficient crushing and stirring operation to the raw materials that drop into in processing storehouse 3, set up centrifugal dust fall mechanism simultaneously in dog-house position, the dust of avoiding producing at broken stirring in-process is followed the feed inlet position and is gone out, control system integrates the degree height, moreover, the steam generator is simple in structure, high reliability.

As can be seen from the accompanying drawings 1-5 of the specification, in the specific implementation process, the opposite-grinding type crushing structure comprises: guide chute 8, two axis of rotation 9 and two rollers 10, its positional relationship and relation of connection are as follows, guide chute 8 installs on 3 upper end open position in processing storehouse, two equal movable cartridge of axis of rotation 9 are in processing storehouse 3, and the one end of two axis of rotation 9 all runs through in 3 lateral walls in processing storehouse, stretch out outside processing storehouse 3, two rollers 10 all install in the blending bunker, and two equal fixed mounting of rollers 10 are on two axis of rotation 9, and leave between two rollers 10 and be equipped with certain clearance, above-mentioned rotation stirring structure includes: a limiting frame 11, a stirring shaft 12 and a stirring paddle 13, the position relation and the connection relation are as follows, the limiting frame 11 is arranged in the processing bin 3, the limiting frame 11 is positioned below the opposite-rolling type crushing structure, the stirring shaft 12 is arranged in the processing bin 3, the upper end of the stirring shaft 12 is movably inserted on the limiting frame 11, the lower end of the stirring shaft 12 penetrates through the lower end face of the processing bin 3, the stirring shaft 12 is rotatably connected with the limiting frame 11 and the lower end face of the processing bin 3, the stirring paddle 13 is arranged in the processing bin 3, the stirring paddle 13 is fixedly sleeved on the stirring shaft 12, when in use, the driving motor 5 is started, the driving end of the driving motor 5 is controlled to rotate, the driving end of the driving motor 5 rotates to drive the speed reducer 6 to work, the output end of the speed reducer 6 drives the output shaft 7 to rotate, the output shaft 7 rotates to drive the crushing transmission structure to transmit power to the two rotating shafts 9 in, two axis of rotation 9 of control rotate in opposite directions, and then make two epaxial grinding roller 10 of axis of rotation 9 rotate in opposite directions, two grinding roller 10 rotate in opposite directions, extrude the material that enters into in baffle box 8 and smash, the lower part of silo 3 is processed to the material after smashing, when output shaft 7 is pivoted, power is through smashing the (mixing) shaft 12 that the transmission structure transmitted 3 lower parts in the silo, drive (mixing) shaft 12 and rotate, mixing shaft 12 rotates under spacing 11 limiting displacement, and then make the epaxial stirring rake 13 of (mixing) shaft 12 rotate, thereby the realization is to the intensive mixing of material.

As can be seen from fig. 1 to 4, fig. 6 to 7 and fig. 9 of the specification, in the specific implementation process, the crushing transmission structure comprises: the box body 14 is arranged on the side wall of the processing bin 3, the box body 14 is sleeved on one exposed side of the two rotating shafts 9, the first driven gear 15 and the second driven gear 16 are fixedly sleeved on the exposed ends of the two rotating shafts 9 respectively, two ends of the first guide gear 17 are rotatably connected with the side wall of the box body 14, the first guide gear 17 is arranged above the second driven gear 16, two ends of the second guide gear 18 are rotatably connected with the side wall of the box body 14, the second guide gear 18 is arranged below the second driven gear 16, the power transmission assembly is arranged on one side of the second driven gear 16, one end of the power transmission assembly is connected with the output shaft 7, and the transmission chain 19 is meshed with the power transmission assembly in sequence, First guide gear 17, first driven gear 15, second guide gear 18, second driven gear 16 and power transmission assembly, wherein power transmission assembly includes: the device comprises a transmission shaft 20, a transmission gear 21, a power gear 22, a driving gear 23 and a driving chain 24, wherein the transmission shaft 20 is movably arranged in a box body 14, the transmission gear 21 is fixedly sleeved on the transmission shaft 20, the transmission gear 21 is meshed with a transmission chain 19, the power gear 22 is fixedly sleeved on an output shaft 7, the driving gear 23 is fixedly sleeved on the transmission shaft 20, the driving chain 24 is meshed with the power gear 22 and the driving gear 23, when in use, the clockwise driving end of a driving motor 5 is controlled to rotate, the output shaft 7 is controlled to rotate clockwise, the power gear 22 on the output shaft 7 is driven to rotate by the clockwise rotation of the output shaft 7, the driving chain 24 is driven by the rotation of the power gear 22 to move clockwise, the driving chain 24 drives the driving gear 23 on the transmission shaft 20 to rotate clockwise, and the driving gear 23 drives, transmission shaft 20 clockwise rotation, drive transmission gear 21 clockwise rotation on the transmission shaft 20, transmission gear 21 clockwise rotation drives transmission chain 19 and moves, transmission chain 19 moves and drives first leading gear 17 clockwise rotation, simultaneously first driven gear 15 clockwise rotation, second leading gear 18 clockwise rotation, second driven gear 16 anticlockwise rotation, and then control the rotation axis 9 clockwise rotation on the first driven gear 15, and the rotation axis 9 anticlockwise rotation on the second driven gear 16, thereby realize that two rolls on the axis of rotation 9 are the roller 10 and rotate in opposite directions, extrude broken operation to the material.

As can be seen from fig. 1-2, fig. 5-6 and fig. 10 of the specification, in the specific implementation process, the stirring transmission structure comprises: a box body 25, a first bevel gear 26, a connecting shaft 27, a second bevel gear 28, a third bevel gear 29 and a fourth bevel gear 30, the positional relationship and the connection relationship are as follows, the box body 25 is arranged on the lower end surface of the processing chamber 3, the box body 25 is arranged below the processing chamber 3, the stirring shaft 12 and the output shaft 7 both extend into the box body 25, the first bevel gear 26 is fixedly sleeved on one end of the output shaft 7, the connecting shaft 27 is arranged in the box body 25, the second bevel gear 28 is fixedly sleeved on the lower end of the stirring shaft 12, the third bevel gear 29 is fixedly sleeved on one end of the connecting shaft 27, the third bevel gear 29 is meshed with the first bevel gear 26, the fourth bevel gear 30 is fixedly sleeved on the other end of the connecting shaft 27, the fourth bevel gear 30 is meshed with the second bevel gear 28, when the driving motor 5 controls the output shaft 7 to rotate, the first bevel gear 26 in the box body 25 on one end of the output shaft 7 rotates, the first bevel gear 26 rotates to drive a third bevel gear 29 which is arranged at one end of the connecting shaft 27 and is meshed with the first bevel gear 26 to rotate, the third bevel gear 29 rotates to drive the connecting shaft 27 to rotate, the connecting shaft 27 rotates to drive a fourth bevel gear 30 arranged at the other end of the connecting shaft 27 to rotate, and the fourth bevel gear 30 rotates to drive a second bevel gear 28 arranged at the lower end of the stirring shaft 12 to rotate, so that the rotation control of the stirring shaft 12 is realized.

As can be seen from fig. 1 to 3, fig. 5 and fig. 8 of the specification, in the specific implementation process, the lifting adjusting structure includes: support frame 31, first pneumatic cylinder 32, four flexible posts 33 and dust cage 34, its position relation and relation of connection are as follows, support frame 31 installs on mount 2, first pneumatic cylinder 32 installs on support frame 31 along the vertical direction, four flexible posts 33 install respectively on support frame 31 lower extreme, and four flexible posts 33 are located the four corners position of first pneumatic cylinder 32 respectively, dust cage 34 installs on the activity of first pneumatic cylinder 32 holds, and dust cage 34 is connected with four flexible posts 33, wherein the centrifugal dust removal structure includes: a dust box 35, an air guiding pipe 36, a cloth bag dust removing net 37 and a centrifugal fan 38, the position relation and the connection relation are as follows, the dust box 35 is arranged on the fixed mount 2, one end of the air guiding pipe 36 is connected with the dust box 35, the other end of the air guiding pipe 36 is communicated with a dust collecting cover 34, the cloth bag dust removing net 37 is arranged in the dust box 35, the centrifugal fan 38 is arranged at one side of the dust box 35, the air inlet end of the centrifugal fan 38 is communicated with the dust box 35, when in use, the centrifugal fan 38 at one end of the dust box 35 on the fixed mount 2 is started, the raised dust returned from the material guiding groove 8 enters the dust box 35 through the dust collecting cover 34 and the air guiding pipe 36 and is dedusted and filtered through the cloth bag dust removing net 37 in the dust box 35, when the raised dust is serious, the expansion of the movable end of the first hydraulic cylinder 32 can be controlled by starting the first hydraulic cylinder 32 on the supporting, the movable end of the first hydraulic cylinder 32 is expanded to push the dust hood 34 to move downwards under the limiting action of the four telescopic columns 33, the opening position of the upper end of the material guide chute 8 is temporarily closed, and when the material needs to be fed, the dust hood 34 is lifted upwards.

As can be seen from fig. 1 to 6 of the specification, in the specific implementation process, the auxiliary material adding mechanism includes: conveyer 39, add silo 40 and supplementary water injection structure, its positional relationship and relation of connection are as follows, and conveyer 39 installs on mount 2, adds silo 40 and installs on the row's of conveyer 39 material is served, and the one end that adds silo 40 stretches into in processing storehouse 3, and supplementary water injection structure is installed on mount 2, and the one end and the processing storehouse 3 of supplementary water injection structure are linked together, and wherein supplementary water injection structure includes: the water tank 41 is arranged on the fixed frame 2, the water supply pump 42 is arranged on the water tank 41, the water inlet end of the water supply pump 42 is communicated with the water tank 41, one end of the water supply pipe 43 is communicated with the water outlet end of the water supply pump 42, the other end of the water supply pipe 43 is communicated with the processing bin 3, and the electromagnetic flow valve 44 is fixedly sleeved on the water supply pipe 43.

To sum up, the high-efficiency single-power crushing and stirring device for building is characterized in that a crushing and stirring mechanism is arranged in a processing bin 3, various raw materials are put into the processing bin 3 by matching with an auxiliary feeding mechanism, the crushing and stirring mechanism is controlled by a single-power output mechanism arranged on a base 1, the raw materials put into the processing bin 3 are efficiently crushed and stirred, a centrifugal dust falling mechanism is arranged at a feeding port, the dust generated in the crushing and stirring process is prevented from being scattered from the feeding port, the control system is high in integration degree, simple in structure and high in reliability, the problems that the structure is complex, the energy consumption is high and the environmental pollution is caused in the working process of the existing raw material crushing and mixing device for building engineering are solved, namely, the generated dust is scattered from the feeding port when the device is used for crushing and mixing raw materials, the waste gas is directly discharged into the air, so that the environmental pollution is caused, and meanwhile, the waste gas has the problem of harm to workers.

The technical solutions described above only represent the preferred technical solutions of the present invention, and some possible modifications to some parts of the technical solutions by those skilled in the art all represent the principles of the present invention, and fall within the protection scope of the present invention.

Claims

1. The efficient single-power crushing and stirring equipment for the building comprises a base (1), a fixing frame (2) and a processing bin (3), and is characterized in that the fixing frame (2) is arranged on the base (1), the processing bin (3) is arranged on the fixing frame (2), the upper part of the processing bin (3) is rectangular, the lower part of the processing bin is cylindrical, a discharge door (4) is arranged on the side wall of the processing bin (3), a crushing and stirring mechanism is arranged in the processing bin (3), a single-power output mechanism is arranged on the base (1), the single-power output mechanism is connected with the crushing and stirring mechanism, an auxiliary feeding mechanism is arranged on one side of the processing bin (3), and a centrifugal dust-settling mechanism is arranged above the processing bin (3);

the opposite-grinding type crushing structure is arranged in the processing bin (3), the rotary stirring structure is arranged in the processing bin (3), and the rotary stirring structure is positioned below the opposite-grinding type crushing structure;

the single power output mechanism includes: the device comprises a driving motor (5), a speed reducer (6), an output shaft (7), a crushing transmission structure and a stirring transmission structure;

the driving motor (5) is arranged on the base (1), the speed reducer (6) is arranged on the base (1), the input end of the speed reducer (6) is connected with the driving end of the driving motor (5), the output shaft (7) is arranged on the output end of the speed reducer (6), the crushing transmission structure is arranged on the opposite-grinding type crushing structure and is connected with the output shaft (7), and the stirring transmission structure is arranged on the lower end of the rotary stirring structure and is connected with the output shaft (7);

the lifting adjusting structure is arranged on the fixed frame (2) and is positioned at the upper end of the processing bin (3), and the centrifugal dust removing structure is arranged at the lower end of the lifting adjusting structure.

2. The high-efficiency single-power crushing and stirring device for buildings according to claim 1, wherein the counter-grinding type crushing structure comprises: a material guide groove (8), two rotating shafts (9) and two grinding rollers (10);

install baffle box (8) in on the open position of processing storehouse (3) upper end, two equal activity cartridge of axis of rotation (9) in processing storehouse (3), and two the one end of axis of rotation (9) all run through in processing storehouse (3) lateral wall, stretch out outside processing storehouse (3), two it all installs in the blending bunker, and two to roll roller (10) equal fixed mounting in two axis of rotation (9), and two it is equipped with certain clearance to reserve between roll roller (10).

3. The high-efficiency single-power crushing and stirring device for building of claim 2, wherein the rotary stirring structure comprises: a limiting frame (11), a stirring shaft (12) and a stirring paddle (13);

spacing (11) install in processing storehouse (3), just spacing (11) are located to rolling formula crushing structure below, (mixing) shaft (12) install in processing storehouse (3), the upper end activity cartridge of (mixing) shaft (12) in on spacing (11), the lower extreme of (mixing) shaft (12) run through in terminal surface under processing storehouse (3), (mixing) shaft (12) with the lower terminal surface of spacing (11) and processing storehouse (3) rotates to be connected, stirring rake (13) install in processing storehouse (3), just stirring rake (13) fixed suit in on (mixing) shaft (12).

4. The high-efficiency single-power crushing and stirring device for buildings according to claim 3, wherein the crushing transmission structure comprises: the box body (14), a first driven gear (15), a second driven gear (16), a first guide gear (17), a second guide gear (18), a power transmission assembly and a transmission chain (19);

the box body (14) is arranged on the side wall of the processing bin (3), the box body (14) is sleeved on the exposed side of the two rotating shafts (9), the first driven gear (15) and the second driven gear (16) are respectively fixedly sleeved on the exposed ends of the two rotating shafts (9), the two ends of the first guide gear (17) are rotatably connected with the side wall of the box body (14), the first guide gear (17) is arranged above the second driven gear (16), the two ends of the second guide gear (18) are rotatably connected with the side wall of the box body (14), the second guide gear (18) is arranged below the second driven gear (16), the power transmission assembly is arranged on one side of the second driven gear (16), one end of the power transmission assembly is connected with the output shaft (7), and the transmission chain (19) is sequentially meshed with the power transmission assembly, The device comprises a first guide gear (17), a first driven gear (15), a second guide gear (18), a second driven gear (16) and a power transmission assembly.

5. The high-efficiency single-power crushing and stirring device for buildings according to claim 4, wherein the power transmission assembly comprises: the transmission mechanism comprises a transmission shaft (20), a transmission gear (21), a power gear (22), a driving gear (23) and a driving chain (24);

the transmission shaft (20) is movably arranged in the box body (14), the transmission gear (21) is fixedly sleeved on the transmission shaft (20), the transmission gear (21) is meshed with the transmission chain (19), the power gear (22) is fixedly sleeved on the output shaft (7), the driving gear (23) is fixedly sleeved on the transmission shaft (20), and the driving chain (24) is meshed with the power gear (22) and the driving gear (23).

6. The high-efficiency single-power crushing and stirring device for the building as claimed in claim 5, wherein the stirring transmission structure comprises: a box body (25), a first bevel gear (26), a connecting shaft (27), a second bevel gear (28), a third bevel gear (29) and a fourth bevel gear (30);

the box body (25) is arranged on the lower end surface of the processing bin (3), the box body (25) is arranged below the processing bin (3), the stirring shaft (12) and the output shaft (7) both extend into the box body (25), the first bevel gear (26) is fixedly sleeved on one end of the output shaft (7), the connecting shaft (27) is arranged in the box body (25), the second bevel gear (28) is fixedly sleeved on the lower end of the stirring shaft (12), the third bevel gear (29) is fixedly sleeved at one end of the connecting shaft (27), the third bevel gear (29) is meshed with the first bevel gear (26), the fourth bevel gear (30) is fixedly sleeved on the other end of the connecting shaft (27), and said fourth bevel gear (30) meshes with said second bevel gear (28).

7. The high-efficiency single-power crushing and stirring device for buildings according to any one of claims 1 to 6, wherein the lifting adjusting structure comprises: a support frame (31), a first hydraulic cylinder (32), four telescopic columns (33) and a dust collection cover (34);

the support frame (31) is arranged on the fixed frame (2), the first hydraulic cylinder (32) is arranged on the support frame (31) along the vertical direction, the four telescopic columns (33) are arranged on the lower end of the support frame (31) respectively, the four telescopic columns (33) are arranged on the four corners of the first hydraulic cylinder (32) respectively, the dust collection cover (34) is arranged on the movable end of the first hydraulic cylinder (32), and the dust collection cover (34) is connected with the four telescopic columns (33).

8. The high-efficiency single-power crushing and stirring device for buildings according to claim 7, wherein the centrifugal dust removing structure comprises: a dust removal box (35), an induced draft tube (36), a cloth bag dust removal net (37) and a centrifugal fan (38);

dust removal case (35) install in on mount (2), induced duct (36) one end with dust removal case (35) are connected, the other end of induced duct (36) with dust cage (34) are linked together, sack dust removal net (37) install in dust removal case (35), centrifugal fan (38) install in dust removal case (35) one side, the air inlet end of centrifugal fan (38) with dust removal case (35) are linked together.

9. The high-efficiency single-power crushing and stirring device for buildings according to claim 8, wherein the auxiliary feeding mechanism comprises: a conveyor (39), a material adding groove (40) and an auxiliary water injection structure;

conveyer (39) install in on mount (2), add silo (40) install in the row of conveyer (39) is served, the one end that adds silo (40) stretches into in processing storehouse (3), supplementary water injection structure install in on mount (2), the one end of supplementary water injection structure with processing storehouse (3) are linked together.

10. The high-efficiency single-power crushing and stirring device for buildings according to claim 9, wherein the auxiliary water injection structure comprises: a water tank (41), a water supply pump (42), a water supply pipe (43), and an electromagnetic flow valve (44);

the water tank (41) is arranged on the fixed frame (2), the water supply pump (42) is arranged on the water tank (41), the water inlet end of the water supply pump (42) is communicated with the water tank (41), one end of the water supply pipe (43) is communicated with the water outlet end of the water supply pump (42), the other end of the water supply pipe (43) is communicated with the processing bin (3), and the electromagnetic flow valve (44) is fixedly sleeved on the water supply pipe (43).