CN111906933A

CN111906933A - Concrete production equipment system

Info

Publication number: CN111906933A
Application number: CN202010648004.6A
Authority: CN
Inventors: 胡生庚; 乔志珍
Original assignee: Haidong Jinyuan Commercial Concrete Co Ltd
Current assignee: Foshan Huayue Intellectual Property Operation Co ltd
Priority date: 2020-07-07
Filing date: 2020-07-07
Publication date: 2020-11-10
Anticipated expiration: 2040-07-07
Also published as: CN111906933B

Abstract

The utility model relates to a concrete production facility system relates to concrete production facility's field, and it includes hollow box, locates stirring subassembly in the box, with a plurality of feeder hoppers of box top intercommunication, locate each valve member between feeder hopper and the box and locate each broken subassembly that encircles in the feeder hopper, broken encircle the subassembly including rotate connect in axis of rotation in the feeder hopper, with axis of rotation connection's first motor and rigid coupling in the first stirring vane of axis of rotation perisporium, first stirring vane is latticed. This application has the effect that improves the production quality of concrete.

Description

Concrete production equipment system

Technical Field

The application relates to the field of concrete production equipment, in particular to a concrete production equipment system.

Background

The concrete is a general name of composite materials formed by preparing a gel material, aggregate and water according to a proper proportion and hardening the gel material, and is widely applied to buildings, bridges and the like; the mixing plant is an important device for producing concrete, and during production, various raw materials are uniformly mixed by the mixing plant according to a certain proportion, and then the mixed concrete is output from the mixing plant.

In the related art, the application document with the publication number of CN111251463A discloses a concrete mixing plant, which has the technical scheme that the concrete mixing plant comprises a shell, a vertical plate and a transverse plate; a discharging pipe is fixed at the top of the shell; a discharge pipe is fixed on one side of the shell; a stirring shaft is suspended in the shell, a first bevel gear is fixed on the outer peripheral surface of the stirring shaft, a support shaft is rotatably installed on one side of the vertical plate, and a second bevel gear is fixed at one end of the support shaft; the packing auger is rotatably arranged on the inner side of the vertical plate relative to the side wall of the shell; the top of the transverse plate is provided with a mounting through hole, and a valve mechanism is arranged in the mounting through hole; a first motor is installed on one side of the shell, which is far away from the blanking pipe, and a first belt wheel is fixed at the output end of the first motor; a second belt wheel is rotatably arranged on one side of the shell close to the first motor; a first connecting mechanism is arranged between the first belt wheel and the packing auger; a second connecting mechanism is arranged between the second belt wheel and the supporting shaft. When the belt wheel is used, after the first motor is started, the first motor drives the first belt wheel to rotate, and the first belt wheel drives the second belt wheel to rotate through the transmission belt; after the second connecting mechanism is connected with the second belt wheel and the supporting shaft, the second belt wheel drives the second supporting shaft to rotate, the second supporting shaft drives the first bevel gear to rotate through the second bevel gear, and the first bevel gear drives the stirring shaft to rotate. After concrete is poured into the shell through the discharging pipe, the concrete is stirred by the stirring shaft. After the stirring is finished, opening a valve mechanism, enabling the concrete to fall into the strip-shaped channel through the valve mechanism, connecting the auger and the first belt wheel through the first connecting mechanism, driving the auger to rotate by the first belt wheel, and driving the concrete to be discharged from the discharge port by the auger; and after the first batch of materials is stirred and discharged from the shell, adding the materials into the shell again to stir the next batch of materials.

To the correlation technique among the above-mentioned, the inventor thinks that there is when reinforced in the casing through the unloading pipe, if the material dwell time overlength in the unloading pipe, then can make the material pile up the circumstances of arching and take place in the unloading pipe to the material is difficult to get into the casing according to accurate ratio and leads to the relatively poor defect of concrete quality.

Disclosure of Invention

In order to improve the production quality of concrete, the application provides a concrete production equipment system.

The application provides a concrete production facility system adopts following technical scheme:

the utility model provides a concrete production facility system, includes hollow box, locates stirring subassembly in the box, with a plurality of feeder hoppers of box top intercommunication, locate each valve member between feeder hopper and the box and locate each broken in the feeder hopper encircle the subassembly, it encircles the subassembly including rotating connect in axis of rotation in the feeder hopper, with rotation axis connection's first motor and rigid coupling in the first stirring vane of axis of rotation perisporium, first stirring vane is latticed.

By adopting the technical scheme, during operation, various weighed materials are respectively added into each feed hopper, and after the stirring of the current batch of materials is finished, the valve assembly is opened, and meanwhile, the arch breaking assembly operates; when the arch breaking assembly operates, the first motor drives the rotating shaft to rotate, the rotating shaft can drive the first stirring blade to rotate, and the first stirring blade can stir the accumulated materials in the rotating process, so that the materials can enter the box body more thoroughly, and the materials are prevented from being excessively accumulated in the feed hopper; simultaneously, here because first stirring vane is latticed, consequently first stirring vane alright utilize first stirring vane's net to cut apart the material at the pivoted in-process to make the material get into the box with comparatively indiscriminate form, thereby can make subsequent stirring process more even with the material stirring, thereby can improve the production quality of concrete.

Preferably, first stirring vane include with the fixed frame of axis of rotation rigid coupling and rigid coupling in flexible stirring net in the fixed frame, fixed frame is kept away from one side of axis of rotation is equipped with the opening, flexible stirring net one side extends to in the opening, the box inner wall rigid coupling has the shake material piece, when first stirring vane rotates, flexible stirring net can with shake the collision of material piece.

By adopting the technical scheme, the rotating shaft drives the fixed frame to rotate in the rotating process of the first stirring blade, the flexible stirring net is driven to rotate in the rotating process of the fixed frame, and materials can be stirred when the flexible stirring net rotates; in-process of flexible stirring net stirring, because flexible stirring net is flexible material, therefore flexible stirring net is rotating the in-process and is bumping each other with the shake material piece, and flexible stirring net self just can take place the vibration after flexible stirring net and shake the material piece and bump to can make the material shake on the flexible stirring net and fall, can improve the precision of each material ratio.

Preferably, one side of the flexible stirring net close to the rotating direction is fixedly connected with a plurality of bur blocks, and one end of each bur block far away from the flexible stirring net is a pointed end.

Through adopting above-mentioned technical scheme, the flexible stirring net drives thorn material piece synchronous motion at the pivoted in-process, and thorn material piece alright puncture the material that becomes the fritter when the flexible stirring net motion goes to one side rotation in the material to make the more even material fall into in the box, thereby alright make the stirring subassembly with the more even of material stirring, further improved the production quality of material.

Preferably, establish the box is the basic shaft along vertical direction's axis, and is a plurality of the feeder hopper is followed the circumference equipartition of basic shaft.

Through adopting above-mentioned technical scheme, with the circumference equipartition of a plurality of feeder hoppers along the basic shaft, can make the material get into with the form of dispersion at the in-process that gets into the box, avoid the material to get into too concentrated and lead to the material later stage to be difficult to by the circumstances of stirring to take place in the box.

Preferably, a bulk cargo assembly is arranged in the box body below the valve assembly and located above the stirring assembly, and the bulk cargo assembly comprises a latticed bulk cargo net fixedly connected to the inner wall of the box body and a vibrating motor fixedly connected to the bulk cargo net.

Through adopting above-mentioned technical scheme, the material drops to the bulk cargo after net, and vibrating motor starts to alright add the box with the form of dispersion with the material, make subsequent stirring process can be with more even of material stirring, it has further improved the production quality of concrete.

Preferably, the bulk cargo net is arranged in a circular arc shape with a downward opening, and the central axis of the bulk cargo net is coaxial with the base shaft.

By adopting the technical scheme, the bulk cargo net is arranged into the arc shape, so that the materials can fall from the higher part of the bulk cargo net to the stirring assembly and move to the lower part of the bulk cargo net at the same time; through adopting this kind of bulk cargo mode can be with the more even joining stirring subassembly department of material to can be with the more even of material stirring, further improve the production quality of concrete.

Preferably, the bulk cargo net comprises a plurality of cylindrical filaments which are arranged in a staggered mode, and gaps are formed between adjacent filaments in rows.

Through adopting above-mentioned technical scheme, establish the silk body into cylindricly, reducible material stops on the silk body for the material is more abundant drops to the box in, thereby has further improved the precision of all kinds of material ratios, has improved the production quality of concrete.

Preferably, the valve assembly comprises two material stopping plates which are slidably connected with the inner wall of the box body along opposite directions, a bidirectional screw rod which is rotatably connected with the box body, and a second motor which is connected with the bidirectional screw rod, the two material stopping plates can seal the bottom of the feed hopper, and the two material stopping plates are in threaded connection with different thread sections of the bidirectional screw rod.

By adopting the technical scheme, when the valve component is opened, the second motor drives the two-way screw to rotate, the two material stopping plates can be driven to rotate relatively when the two-way screw rotates, and the two material stopping plates can move towards opposite directions in the process of relative rotation of the two-line screw; when the two material stopping plates move towards the opposite side, the discharge end of the feed hopper is closed, and when the two material stopping plates move towards the opposite side, the discharge end of the feed hopper is opened, so that the feed hopper is communicated with the inner wall of the box body, and therefore materials in the feed hopper can enter the box body; the opening and closing mode has a simple structure, and the discharging ends of the feeding hoppers can be opened or closed at one time.

Preferably, the stirring assembly comprises a stirring shaft rotatably connected in the box body, a second stirring blade fixedly connected to the peripheral wall of the stirring shaft, and a third motor connected with the stirring shaft.

By adopting the technical scheme, when the stirring assembly works, the third motor drives the stirring shaft to rotate, the stirring shaft drives the plurality of second stirring blades to synchronously rotate when rotating, and materials can be uniformly stirred in the rotating process of the second stirring blades; the stirring mode has simple structure, stable operation and lower cost.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the arch breaking assembly is arranged to stir and scatter the caked materials into the box body, so that the problem that the ratio of various materials is reduced due to the fact that the materials are accumulated in the feed hopper can be avoided, the materials can be scattered into the box body more uniformly, the materials can be stirred more uniformly in the subsequent stirring process, and the production quality of concrete is improved;

2. the flexible stirring net vibrates due to the mutual collision of the flexible stirring net and the vibration block, so that materials can more thoroughly enter the box body, and the material proportioning accuracy can be further improved;

3. can get into the box with more in disorder form with the material through setting up the bulk cargo subassembly in to can be convenient for follow-up stirring subassembly more even with the material stirring.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG. 2 is a partial schematic view of the plane A-A of FIG. 1;

FIG. 3 is an enlarged partial schematic view of portion A of FIG. 2;

FIG. 4 is a partial schematic view of the plane B-B of FIG. 1;

FIG. 5 is an enlarged partial schematic view of portion B of FIG. 2;

FIG. 6 is an enlarged partial schematic view of portion C of FIG. 2;

description of reference numerals: 1. a box body; 11. a feed hopper; 2. an arch breaking assembly; 21. a rotating shaft; 22. a first motor; 23. a first stirring blade; 231. a fixing frame; 232. a flexible stirring net; 233. a thorn block; 234. an opening; 235. a seismic mass; 3. a valve assembly; 31. a material stopping plate; 32. a bidirectional screw; 33. a lead screw nut; 34. a second motor; 4. a guide assembly; 41. a guide rail; 42. a guide block; 5. a stirring assembly; 51. a stirring shaft; 52. a second stirring blade; 53. a third electric machine; 6. a bulk material net; 61. a filament body; 62. a gap; 63. a vibration motor.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses concrete production equipment system. Referring to fig. 1 and 2, a concrete production equipment system includes a hollow box 1, a discharge port opened at the bottom of the box 1, a valve installed at the discharge port, a plurality of feed hoppers 11 communicated with the top of the box 1, an arch breaking assembly 2 installed in each feed hopper 11, a valve assembly 3 installed between each feed hopper 11 and the box 1, a stirring assembly 5 installed in the box 1, and a bulk material assembly installed between the valve assembly 3 and the stirring assembly 5.

Referring to fig. 1 and 2, 1 inner chamber of box is the rectangle form, establishes box 1 and is equipped with 5 for the basic shaft along the axis of vertical direction, and 5 feeder hoppers 11 are equipped with 5 in this embodiment, and 5 feeder hoppers 11 equal along the circumference equipartition of basic shaft and each feeder hopper 11 apart from the horizontal distance of basic shaft.

Referring to fig. 2 and 3, the cross section of the inner wall of the feeding hopper 11 is rectangular, the arch breaking assembly 2 includes a rotating shaft 21 connected to the inner wall of the feeding hopper 11 in a rotating manner and having a horizontal axis, a first motor 22 connected to the rotating shaft 21, and a first stirring blade 23 fixedly connected to the peripheral wall of the rotating shaft 21, in this embodiment, the first motor 22 is a servo motor, the first motor 22 is fixedly connected to the outer wall of the feeding hopper 11 through a screw, and an output shaft of the first motor 22 passes through the peripheral wall of the feeding hopper 11 and is coaxially and fixedly connected to the rotating shaft 21 through. The first stirring blade 23 comprises a fixing frame 231 welded with the rotating shaft 21 and a flexible stirring net 232 fixedly connected in the fixing frame 231, the flexible stirring net 232 is made of polyethylene plastics in the embodiment, one side of the flexible stirring net 232 close to the rotating direction is integrally and fixedly connected with a plurality of thorn blocks 233, and one end of each thorn block 233 far away from the flexible stirring net 232 is a pointed end; an opening 234 is formed in one side of the fixing frame 231, which is far away from the rotating shaft 21, and one side of the flexible stirring net 232 extends into the opening 234; the inner wall of the box body 1 is welded with the seismic material blocks 235, in this embodiment, there are two seismic material blocks 235, the two seismic material blocks 235 and the stirring shaft 51 are disposed on the same horizontal plane, and the two seismic material blocks 235 are symmetrically disposed on two sides of the axis direction of the rotating shaft 21, when the first stirring blade 23 rotates, the flexible stirring net 232 can collide with the seismic material blocks 235.

Referring to fig. 2 and 4, the valve assembly 3 includes two material stopping plates 31 slidably connected to the top wall of the inner cavity of the box 1 in opposite directions, a two-way screw 32 rotatably connected to the box 1, screw nuts 33 respectively connected to two threaded sections of the two-way screw 32, and a second motor 34 connected to the two-way screw 32, the two material stopping plates 31 are respectively welded to one screw nut 33 in one-to-one correspondence, the two material stopping plates 31 can seal the bottom of the feeding hopper 11, and when the two material stopping plates 31 move to opposite sides to contact each other, the top walls of the two material stopping plates 31 seal the opening 234 at the lower end of the material stopping plates 31; in the embodiment, the second motor 34 is a servo motor, the second motor 34 is fixedly connected to the outer wall of the box body 1 through a screw, and an output shaft of the second motor 34 penetrates through the side wall of the box body 1 and is coaxially and fixedly connected with the bidirectional screw 32 through a coupler; the second screw rod is arranged on one side of the motion direction of the two material stopping plates 31, a group of guide assemblies 4 are arranged on the top wall of the inner cavity of the box body 1 on the other side of the motion direction of the two material stopping plates 31, each guide assembly 4 comprises a guide rail 41 which is coaxially arranged with the two-way screw rod 32 and welded with the top wall of the inner wall of the box body 1 and two guide blocks 42 which are slidably connected with the guide rails 41 along the axial direction of the two-way screw rod 32, and one material stopping plate 31 is welded on each guide block 42 in a.

Referring to fig. 5, the bulk cargo subassembly includes latticed bulk cargo net 6 of rigid coupling in the inner wall of box 1 and vibrating motor 63 through screw rigid coupling in bulk cargo net 6 diapire, and bulk cargo net 6 includes the cylindrical silk body 61 of many crisscross arrangements each other, and the material of silk body 61 is the steel wire that the diameter is 0.5mm in this embodiment, and the row forms gapped 62 between the adjacent silk body 61, and bulk cargo net 6 is the downward arc setting of opening 234 and the central axis of bulk cargo net 6 is coaxial with the basal axis.

Referring to fig. 6, the stirring assembly 5 includes a stirring shaft 51 rotatably connected in the box 1, a second stirring blade 52 fixedly connected to a peripheral wall of the stirring shaft 51, and a third motor 53 connected to the stirring shaft 51, in this embodiment, the third motor 53 is a servo motor, the third motor 53 is fixedly connected to an outer wall of the box 1 through a screw, an output shaft of the third motor 53 passes through the box 1 and is coaxially and fixedly connected to the stirring shaft 51 through a coupler, the second stirring blade 52 is spiral, and the second stirring blade 52 is spirally wound around the peripheral wall of the stirring shaft 51.

The implementation principle of a concrete production equipment system in the embodiment of the application is as follows: when the valve assembly is used, different types of raw materials are weighed and then added into the feed hopper 11 for temporary storage, in the process, the sides, opposite to the two material stopping plates 31, in the valve assembly 3 are in contact with each other, and at the moment, the two material stopping plates 31 close the port at the bottom of the feed hopper 11; after the previous batch of materials in the box body 1 is stirred and discharged, the valve component 3 is opened, and then the materials in the feed hopper 11 can fall onto the bulk material net 6.

When the valve component 3 is opened and closed, the second motor 34 drives the two-way screw 32 to rotate, in the process of rotating the two-way screw 32, due to the guiding effect of the guide rail 41 and the guide block 42 on the material stopping plate 31, the material stopping plate 31 can move towards opposite directions or opposite directions along the direction parallel to the axis of the two-way screw 32, the port of the feeding hopper 11 is closed when the two material stopping plates 31 move relatively, and the port of the feeding hopper 11 is opened when the two material stopping plates 31 move towards opposite directions.

Before, during and after the valve component 3 is opened, the first motor 22 drives the rotating shaft 21 to rotate, the rotating shaft 21 drives the flexible stirring net 232 to rotate in the rotating process, the barbed material block 233 is driven to synchronously rotate when the flexible stirring net 232 rotates, and the materials can be broken in the rotating process of the flexible stirring net 232 and the barbed material block 233.

The material that drops to on the bulk cargo net 6 passes the clearance 62 that the silk body 61 formed and drops to stirring subassembly 5, and at this in-process, vibrating motor 63 drives bulk cargo net 6 vibration, and the in-process material of vibrating motor 63 vibration alright drop to stirring subassembly 5 department.

After the material drops to stirring subassembly 5 department, third motor 53 drives (mixing) shaft 51 and rotates, drives second stirring vane 52 synchronous rotation when (mixing) shaft 51 rotates, and second stirring vane 52 pivoted in-process alright stir the material, opens the valve after stirring the material and discharges the material from the bin outlet.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. A concrete production facility system characterized by: including hollow box (1), locate stirring subassembly (5) in box (1), with a plurality of feeder hoppers (11) of box (1) top intercommunication, locate each valve member (3) between feeder hopper (11) and box (1) and locate each broken subassembly (2) that encircles in feeder hopper (11), broken subassembly (2) that encircles including rotate connect in axis of rotation (21) in feeder hopper (11), with first motor (22) and rigid coupling that axis of rotation (21) are connected in first stirring vane (23) of axis of rotation (21) perisporium, first stirring vane (23) are latticed.

2. A concrete production facility system according to claim 1, wherein: first stirring vane (23) include with fixed frame (231) and rigid coupling of axis of rotation (21) rigid coupling in flexible stirring net (232) in fixed frame (231), keep away from fixed frame (231) one side of axis of rotation (21) is equipped with opening (234), flexible stirring net (232) one side extends to in opening (234), box (1) inner wall rigid coupling has shake material piece (235), when first stirring vane (23) rotated, flexible stirring net (232) can with shake material piece (235) collision.

3. A concrete production facility system according to claim 2, wherein: one side of the flexible stirring net (232) close to the rotating direction is fixedly connected with a plurality of thorn blocks (233), and one end of each thorn block (233) far away from the flexible stirring net (232) is a sharp head.

4. A concrete production facility system according to claim 1, wherein: establish box (1) is the basic shaft along the axis of vertical direction, and is a plurality of feeder hopper (11) are followed the circumference equipartition of basic shaft.

5. A concrete production plant system according to claim 4, wherein: the bulk cargo subassembly is equipped with in box (1) in valve component (3) below department, the bulk cargo subassembly is located stirring subassembly (5) top, the bulk cargo subassembly include the rigid coupling in the latticed bulk cargo net (6) of box (1) inner wall and rigid coupling in vibrating motor (63) on bulk cargo net (6).

6. A concrete production facility system according to claim 5, wherein: the bulk cargo net (6) is arranged in a circular arc shape with a downward opening (234), and the central axis of the bulk cargo net (6) is coaxial with the base shaft.

7. A concrete production facility system according to claim 5, wherein: the bulk cargo net (6) comprises a plurality of cylindrical filament bodies (61) which are arranged in a staggered mode, and gaps (62) are formed between adjacent filament bodies (61) in a row mode.

8. A concrete production facility system according to claim 1, wherein: valve member (3) include two along opposite direction with box (1) inner wall sliding connection end flitch (31), with box (1) rotate two-way screw rod (32) of being connected and with second motor (34) that two-way screw rod (32) are connected, two end flitch (31) can with feeder hopper (11) bottom is sealed, two end flitch (31) with the different screw thread section threaded connection of two-way screw rod (32).

9. A concrete production facility system according to claim 1, wherein: the stirring assembly (5) comprises a stirring shaft (51) rotatably connected in the box body (1), a second stirring blade (52) fixedly connected to the peripheral wall of the stirring shaft (51) and a third motor (53) connected with the stirring shaft (51).