CN111111832B

CN111111832B - Broken and system aggregate device of useless brick and tile

Info

Publication number: CN111111832B
Application number: CN202010091617.4A
Authority: CN
Inventors: 不公告发明人
Original assignee: Huvo Porous Gangue Brick Co ltd
Current assignee: HuVo Porous Gangue Brick Co.,Ltd.
Priority date: 2020-02-13
Filing date: 2020-02-13
Publication date: 2020-12-11
Anticipated expiration: 2040-02-13
Also published as: CN111111832A

Abstract

The invention discloses a waste brick and tile crushing and bone material making device, which comprises a feed inlet arranged on the left wall of a box, a feed channel arranged on the right side of the feed inlet, a hammering cavity arranged on the right side of the feed channel, a through cavity arranged right above the hammering cavity, a saw-tooth hammer used for crushing waste bricks and tiles, a first tooth cavity arranged in the box and arranged on the left side of the saw-tooth hammer, and cement powder can be separated from the crushed and bone material without removing a cement layer on the surface, so that the working efficiency is increased; the whole process of preparing the aggregate from the waste bricks and tiles is combined together and is easy to carry; the carrying process of primary processing materials and secondary processing materials in the conventional processing process is omitted, and the most original waste brick and tile materials are added to directly obtain the reusable aggregate.

Description

Broken and system aggregate device of useless brick and tile

Technical Field

The invention relates to the technical field related to construction waste, in particular to a device for crushing waste bricks and tiles and preparing aggregate.

Background

The waste bricks and tiles are one of the main components of the construction waste, and the recycling degree and the recycling way of the waste bricks and tiles directly influence the recycling and industrialization process of the construction waste. The resource utilization of waste bricks and tiles has important significance for developing circular economy and protecting environment, the existing mode can be that the waste bricks and tiles are transported to a special processing factory from a construction garbage site, surface mortar is firstly removed, and then the waste bricks and tiles are recycled by a plurality of treatment modes such as primary treatment, secondary treatment and the like, the middle processing, transportation and carrying processes are more, the utilization process is more troublesome, and the additional cost is higher.

Disclosure of Invention

The invention aims to provide a waste brick and tile crushing and aggregate making device which is used for overcoming the defects in the prior art.

The device for crushing and making bone material of waste tiles comprises a box arranged on the ground, wherein a feed inlet is formed in the left wall of the box, a feed channel is formed in the right side of the feed inlet, a hammering cavity is formed in the right side of the feed channel, a through cavity is formed right above the hammering cavity, a sawtooth hammer for crushing the waste tiles is arranged in the through cavity in a sliding mode, a first tooth cavity located in the box is formed in the left side of the sawtooth hammer, inclined sawteeth are arranged on the bottom surface of the sawtooth hammer, a first concave tooth section is formed in the left wall of the sawtooth hammer, an incomplete gear located in the first tooth cavity is connected to the left side of the first concave tooth section in a meshing mode, the incomplete gear is in key connection with a first rotating shaft, the rear end of the first rotating shaft is rotatably connected with the rear wall of the first tooth cavity, and the front end of the first rotating shaft is connected with a first motor fixedly arranged on the front wall of the first tooth cavity, the right side in hammering chamber is equipped with and is used for blocking the shutter mechanism of useless brick and tile in the hammering chamber, shutter mechanism is including being located the shutter on hammering chamber right side, the right side of shutter is equipped with the toggle mechanism who is used for stirring useless brick and tile, toggle mechanism including being located stir the chamber on shutter right side, set firmly in case and upper surface with the bottom surface in hammering chamber is at same planar extension board, the downside of extension board is equipped with the mechanism of rolling that is used for rolling useless brick and tile after the hammering, roll the mechanism include with stir the chamber intercommunication and be located stir the chamber of rolling of chamber below, it is equipped with the screening mechanism that is used for screening the useless brick and tile after rolling to roll the chamber downside.

On the basis of the technical scheme, the door stopping mechanism further comprises a sliding cavity connected with the door stopping mechanism in a sliding mode, the left side of the sliding cavity is communicated with a second tooth cavity, a second motor is fixedly arranged on the front wall of the second tooth cavity, the rear side of the second motor is connected with a second rotating shaft, the rear end of the second rotating shaft is connected with the rear wall of the second tooth cavity in a rotating mode, a gear is connected to the second rotating shaft in a key mode, and the gear is connected with a second concave tooth section on the left surface of the door stopping mechanism in a meshing mode.

On the basis of the technical scheme, the poking mechanism further comprises a third rotating shaft which is rotatably connected with the front wall of the poking cavity, and six brushes used for brushing the waste brick tiles on the extension plate to the grinding cavity are arranged on the third rotating shaft in an annular array.

On the basis of the technical scheme, rolling mechanism is still including being located roll the section of thick bamboo of rolling of intracavity and bilateral position symmetry, it is left roll a fixedly connected with driving shaft, the front end of driving shaft be connected with set firmly in roll the third motor in the chamber antetheca, right side roll a fixedly connected with driven shaft, the front end of driven shaft with the antetheca in the chamber of rolling rotates and connects.

On the basis of the technical scheme, the driving shaft with the rear end of driven shaft runs through the back wall in rolling chamber and stretching into and being located rolling chamber with stir the transmission chamber at chamber rear and with the back wall in transmission chamber rotates and connects, the rear end of third pivot runs through stir the back wall in chamber and stretch into and be located rolling chamber with stir the chamber rear the transmission chamber and with the back wall in transmission chamber rotates and connects, the key connection has to be located on the driving shaft the inside driving gear in transmission chamber, the key connection has to be located on the driven shaft the transmission intracavity portion and with driven gear that the driving gear meshing is connected, the driven shaft pass through the belt with the third pivot area is connected.

On the basis of the technical scheme, the screening mechanism comprises a fourth motor positioned in the front wall of the rolling cavity, the rear surface of the fourth motor is connected with a fourth rotating shaft of which the rear end is rotatably connected with the rear wall of the rolling cavity, a cam is fixedly arranged on the fourth rotating shaft, a fine screen of which the upper end is in sliding connection with the rolling cavity and is used for screening cement powder is abutted against the upper part of the cam, the left lower end of the fine screen is fixedly connected with a fine aggregate screen for screening fine aggregates, a screening cavity is communicated with the lower part of the rolling cavity, a fifth rotating shaft fixedly connected with the fine aggregate screen is rotatably connected on the front and rear walls of the screening cavity, a collecting box is slidably connected on the left and right walls of the screening cavity, a handle for pushing and pulling the collecting box is arranged on the front wall of the collecting box, a mud powder cavity for collecting cement powder is arranged in the collecting box under the fine screen, a fine aggregate cavity which is positioned in the collection box and on the left side of the mud powder cavity and used for collecting fine aggregates is arranged under the fine aggregate sieve, and a coarse aggregate cavity which is positioned in the collection box is arranged on the left side of the fine aggregate cavity.

The invention has the beneficial effects that: the cement layer on the surface is not required to be removed, the crushing and bone material making can be directly carried out, the cement powder is separated, and the working efficiency is increased; combine the whole flow of waste brick and tile system aggregate together and easily carry, be fit for being used for places such as waste brick and tile recovery field, directly process the waste brick and tile that retrieves, make the aggregate that can reuse and transport the place that needs to use, remove the step that waste brick and tile transported the processing factory from, also left out in the conventional course of working to the primary processed material, the handling process of reworking material again, it can directly obtain the aggregate that can reuse to drop into the most primitive waste brick and tile material.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of a waste tile crushing and aggregate making device according to the present invention;

FIG. 2 is a schematic view of the present invention taken along the line A-A of FIG. 1;

FIG. 3 is a schematic view of the present invention taken along the line B-B of FIG. 1;

FIG. 4 is a schematic view of the present invention taken along the line C-C of FIG. 1;

FIG. 5 is a schematic view of the structure of FIG. 1 in the direction D-D according to the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 5, the device for crushing and making bone material of waste tiles according to the embodiment of the present invention includes a box 20 installed on the ground, a feeding hole 31 is provided on a left wall of the box 20, a feeding channel 32 is provided on a right side of the feeding hole 31, a hammering cavity 34 is provided on a right side of the feeding channel 32, a through cavity 21 is provided right above the hammering cavity 34, a saw-tooth hammer 22 for crushing waste tiles is slidably installed in the through cavity 21, a first tooth cavity 23 located inside the box 20 is provided on a left side of the saw-tooth hammer 22, inclined saw teeth 33 are provided on a bottom surface of the saw-tooth hammer 22, a first concave tooth section 65 is provided on a left wall of the saw-tooth hammer 22, an incomplete gear 24 located inside the first tooth cavity 23 is engaged and connected to a left side of the first concave tooth section 65, the incomplete gear 24 is keyed with a first rotating shaft 25, a rear end of the first rotating shaft 25 is rotatably connected to a rear wall of the first tooth cavity 23, the front end of first pivot 25 is connected with set firmly in the first motor 55 of first tooth chamber 23 antetheca, the right side in hammering chamber 34 is equipped with and is used for blocking the shutter mechanism 801 of useless brick and tile in hammering chamber 34, shutter mechanism 801 is including being located shutter 35 on hammering chamber 34 right side, the right side of shutter 35 is equipped with the toggle mechanism 802 that is used for stirring useless brick and tile, toggle mechanism 802 including being located stir chamber 37 on shutter 35 right side, set firmly in case 20 and upper surface with the bottom surface in same plane extension board 38 in hammering chamber 34, the downside of extension board 38 is equipped with rolls the mechanism 803 that is used for rolling useless brick and tile after hammering, roll mechanism 803 include with stir chamber 37 intercommunication and be located stir the chamber 41 of chamber 37 below, it is equipped with the screening mechanism 804 that is used for screening the useless brick and tile after rolling to roll chamber 41 downside, start first motor 55, first pivot 25 rotates and drives incomplete gear 24 anticlockwise rotation, works as first concave tooth section 65 with incomplete gear 24 breaks away from the meshing and connects, sawtooth hammer 22 is along under self action of gravity lead to chamber 21 and fall and hammer useless brick and tile, works as incomplete gear 24 rotates a week after, incomplete gear 24 again with first concave tooth section 65 meshes and drives sawtooth hammer 22 rises until first concave tooth section 65 with incomplete gear 24 breaks away from the meshing and connects, accomplishes a round and strikes the action, and is accomplished till useless brick and tile is accomplished the preliminary broken completion.

In addition, in an embodiment, the shutter mechanism 801 further includes a sliding cavity 30 slidably connected to the shutter 35, the left side of the sliding cavity 30 is connected to a second tooth cavity 29, a second motor 56 is fixedly disposed on the front wall of the second tooth cavity 29, the rear side of the second motor 56 is connected to a second rotating shaft 27, the rear end of the second rotating shaft 27 is rotatably connected to the rear wall of the second tooth cavity 29, a gear 28 is connected to the second rotating shaft 27 in a key manner, the gear 28 is in meshing connection with a second concave tooth section 45 on the left surface of the shutter 35, when the second motor 56 is started, the shutter 35 slides downward until the bottom end of the shutter 35 abuts against the bottom wall of the sliding cavity 30, at this time, the upper surface of the shutter 35 is in the same plane with the upper surfaces of the hammering cavity 34 and the extending plate 38, and the hammering cavity 34 is connected to the poking cavity 37, when a hammered waste tile is scratched into the poking cavity 37 under the action of an inclined plane and a gravity, the second motor 56 is reversed to raise the shutter 35 until the upper end of the shutter 35 abuts the top wall of the toggle chamber 37.

In addition, in one embodiment, the toggle mechanism 802 further comprises a third shaft 60 rotatably connected to the front wall of the toggle chamber 37, and six brushes 36 are arranged on the third shaft 60 in an annular array for brushing waste bricks on the extension plate 38 into the rolling chamber 41.

In addition, in one embodiment, the rolling mechanism 803 further includes a rolling cylinder 39 located in the rolling cavity 41 and symmetrical in left and right positions, the left rolling cylinder 39 is fixedly connected with a driving shaft 46, the front 7 end of the driving shaft 46 is connected with a third motor 58 fixedly arranged in the front wall of the rolling cavity 41, the right rolling cylinder 39 is fixedly connected with a driven shaft 40, and the front end of the driven shaft 40 is rotatably connected with the front wall of the rolling cavity 41.

In addition, in one embodiment, the rear end of the driving shaft 46 and the driven shaft 40 penetrates through the rear wall of the rolling cavity 41 and extends into the transmission cavity 59 behind the rolling cavity 41 and the toggle cavity 37 and is rotatably connected with the rear wall of the transmission cavity 59, the rear end of the third rotating shaft 60 penetrates through the rear wall of the toggle cavity 37 and extends into the transmission cavity 59 behind the rolling cavity 41 and the toggle cavity 37 and is rotatably connected with the rear wall of the transmission cavity 59, the driving shaft 46 is keyed with the driving gear 44 inside the transmission cavity 59, the driven shaft 40 is keyed with the driven gear 43 inside the transmission cavity 59 and in meshing connection with the driving gear 44, the driven shaft 40 is in belt connection with the third rotating shaft 60 through a belt 61, when the third motor 58 is started, the driving shaft 46 drives the driven shaft 40 to rotate and drives the third rotating shaft 60 to rotate through the belt 61, the brushes 36 brush the waste tiles on the extension plates 38 into the rolling cavities 41, and the rolling cylinders 39 on the left and right sides rotate in opposite directions through gear pairs and roll the waste tiles.

In addition, in one embodiment, the screening mechanism 804 includes a fourth motor 64 located in the front wall of the grinding chamber, a rear surface of the fourth motor 64 is connected with a fourth rotating shaft 63 with a rear end rotatably connected with the rear wall of the grinding chamber 41, a cam 42 is fixedly mounted on the fourth rotating shaft 63, a fine screen 48 with an upper end slidably connected with the grinding chamber 41 and used for screening cement powder is abutted on the upper side of the cam 42, a fine aggregate screen 49 used for screening fine aggregate is fixedly connected to the left lower end of the fine screen 48, a screening chamber 54 is communicated below the grinding chamber 41, a fifth rotating shaft 47 fixedly connected with the fine aggregate screen 49 is rotatably connected to the front and rear walls of the screening chamber 54, a collecting box 53 is slidably connected to the left and right walls of the screening chamber 54, a handle 57 used for pushing and pulling the collecting box 53 is arranged on the front wall of the collecting box 53, a mud powder chamber 50 located in the collecting box 53 and used for collecting cement powder is arranged right below the fine screen 48, the fine aggregate sieve 49 is provided with a fine aggregate cavity 51 which is positioned in the collection box 53 and on the left side of the mud powder cavity 50 and used for collecting fine aggregates, the left side of the fine aggregate cavity 51 is provided with a coarse aggregate cavity 52 which is positioned in the collection box 53, the fourth motor 64 is started, the rotation of the cam 42 drives the fine sieve 48 and the fine aggregate sieve 49 to do vibrating motion with the fifth rotating shaft 47 as a rotating center, cement powder falls into the mud powder cavity 50 through the fine sieve 48, the fine aggregate slides down the fine sieve 48 and the fine aggregate sieve 49 in the vibrating motion and falls onto the fine aggregate sieve 49 and into the fine aggregate cavity 51, and the coarse aggregate slides out the fine sieve 49 and the fine aggregate cavity 52 in the vibrating motion of the fine sieve 48 and the fine aggregate sieve 49.

In the initial state, the upper end of the shutter 35 abuts against the top wall of the toggle cavity 37, the first concave tooth section 65 is in meshing connection with the incomplete gear 24, and the sawtooth hammer 22 is located at the highest position.

When the waste tiles are required to be crushed, the waste tiles are placed into the feeding hole 31 and slide into the hammering cavity 34 through the feeding channel 32, then the first motor 55 is started, the first rotating shaft 25 rotates and drives the incomplete gear 24 to rotate anticlockwise, when the first concave tooth section 65 is disengaged and connected with the incomplete gear 24, the saw-tooth hammer 22 falls down along the through cavity 21 under the action of self gravity and hammers the waste tiles, after the incomplete gear 24 rotates for a circle, the incomplete gear 24 is engaged with the first concave tooth section 65 again and drives the saw-tooth hammer 22 to ascend until the first concave tooth section 65 is disengaged and connected with the incomplete gear 24, a hammering action is completed, and the first motor 55 is turned off until the waste tiles are crushed primarily and the highest point of the saw-tooth hammer 22 is reached,

after the preliminary crushing is finished, the second motor 56 is started, the shutter 35 slides downwards until the bottom end of the shutter 35 abuts against the bottom wall of the sliding cavity 30 and the second motor 56 is closed, at the moment, the upper surface of the shutter 35, the hammering cavity 34 and the upper surface of the extension plate 38 are on the same plane, the hammering cavity 34 is communicated with the stirring cavity 37, after the hammered waste tile slides into the stirring cavity 37 under the action of the inclined plane and the gravity, the second motor 56 is reversed to lift the shutter 35 until the upper end of the shutter 35 abuts against the top wall of the stirring cavity 37 and the second motor 56 is closed,

then the third motor 58 is started, the driving shaft 46 drives the driven shaft 40 to rotate and drives the third rotating shaft 60 to rotate through the belt 61, so that the brush 36 brushes the waste bricks and tiles on the extension plate 38 into the grinding cavity 41, the grinding cylinders 39 on the left side and the right side rotate oppositely through the gear pair and grind the waste bricks and tiles, the third motor 58 is finished after grinding is finished,

after the rolled waste brick tiles fall on the fine screen 48, the fourth motor 64 is started, the rotation of the cam 42 drives the fine screen 48 and the fine aggregate screen 49 to do vibrating motion with the fifth rotating shaft 47 as a rotating center, cement powder falls into the mud powder cavity 50 through the fine screen 48, fine aggregate slides down on the fine aggregate screen 49 and falls into the fine aggregate cavity 51 under the vibrating motion of the fine screen 48 and the fine aggregate screen 49, coarse aggregate slides out of the fine aggregate screen 49 and falls into the coarse aggregate cavity 52 under the vibrating motion of the fine screen 48 and the fine aggregate screen 49, the fourth motor 64 is turned off after the screening is finished, the collecting box 53 is taken out, and the product in the collecting box 53 is placed in the recovery collecting box 53 to return to the initial state.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and scope of the present invention are intended to be included therein.

Claims

1. The utility model provides a broken and system aggregate device of useless brick and tile, is including installing subaerial case, its characterized in that: the utility model discloses a brick making machine, including case, feed inlet, sawtooth hammer, incomplete gear key and first pivot, be equipped with the feed inlet on the left wall of case, the right side of feed inlet is equipped with the pan feeding passageway, the right side of pan feeding passageway is equipped with the hammering chamber, be equipped with logical chamber directly over the hammering chamber, it has the sawtooth hammer that is used for smashing useless brick and tile to lead to intracavity slidable mounting, the left side of sawtooth hammer is equipped with the first flute profile in the inside of case, the bottom surface of sawtooth hammer is equipped with oblique sawtooth, be equipped with first concave tooth section on the left wall of sawtooth hammer, the left side meshing of first concave tooth section is connected with the incomplete gear that is located in the first flute profile, incomplete gear key is connected with first pivot, the rear end of first pivot with the back wall rotation of first flute profile, the front end of first pivot is connected with set firmly in the first motor of first flute profile antetheca wall, the right side in hammering, the door blocking mechanism comprises a door block positioned on the right side of the hammering cavity, a shifting mechanism used for shifting waste tiles is arranged on the right side of the door block, the shifting mechanism comprises a shifting cavity positioned on the right side of the door block and an extension plate fixedly arranged on the box, the upper surface of the extension plate and the bottom surface of the hammering cavity are positioned on the same plane, a rolling mechanism used for rolling the waste tiles after hammering is arranged on the lower side of the extension plate, the rolling mechanism comprises a rolling cavity communicated with the shifting cavity and positioned below the shifting cavity, and a screening mechanism used for screening the waste tiles after rolling is arranged on the lower side of the rolling cavity; the door stopping mechanism further comprises a sliding cavity in sliding connection with the door stopping mechanism, a second tooth cavity is communicated with the left side of the sliding cavity, a second motor is fixedly arranged on the front wall of the second tooth cavity, the rear side of the second motor is connected with a second rotating shaft, the rear end of the second rotating shaft is rotatably connected with the rear wall of the second tooth cavity, a gear is connected to the second rotating shaft in a key mode, and the gear is meshed with a second concave tooth section on the left surface of the door stopping mechanism; the poking mechanism further comprises a third rotating shaft which is rotatably connected with the front wall of the poking cavity, and six brushes for brushing the waste brick tiles on the extension plate to the rolling cavity are arranged on the third rotating shaft in an annular array; the rolling mechanism further comprises rolling cylinders which are positioned in the rolling cavity and are symmetrical in left and right positions, the left rolling cylinder is fixedly connected with a driving shaft, the front end of the driving shaft is connected with a third motor fixedly arranged in the front wall of the rolling cavity, the right rolling cylinder is fixedly connected with a driven shaft, and the front end of the driven shaft is rotatably connected with the front wall of the rolling cavity; the rear ends of the driving shaft and the driven shaft penetrate through the rear wall of the rolling cavity and extend into the transmission cavity behind the rolling cavity and the stirring cavity and are rotatably connected with the rear wall of the transmission cavity, the rear end of the third rotating shaft penetrates through the rear wall of the stirring cavity and extends into the transmission cavity behind the rolling cavity and the stirring cavity and is rotatably connected with the rear wall of the transmission cavity, the driving shaft is in key connection with a driving gear inside the transmission cavity, the driven shaft is in key connection with a driven gear inside the transmission cavity and in meshed connection with the driving gear, and the driven shaft is connected with the third rotating shaft through a belt; the screening mechanism comprises a fourth motor located in the front wall of the rolling cavity, the rear surface of the fourth motor is connected with a fourth rotating shaft, the rear end of the fourth rotating shaft is rotatably connected with the rear wall of the rolling cavity, a cam is fixedly mounted on the fourth rotating shaft, the upper end of the fine screen is connected with the rolling cavity in a sliding mode and is used for screening cement powder, the left lower end of the fine screen is fixedly connected with a fine aggregate screen used for screening fine aggregates, the lower portion of the rolling cavity is communicated with a screening cavity, the front rear wall of the screening cavity is rotatably connected with a fifth rotating shaft fixedly connected with the fine aggregate screen, the left wall and the right wall of the screening cavity are slidably connected with a collecting box, a handle used for pushing and pulling the collecting box is arranged on the front wall of the collecting box, a mud powder cavity used for collecting cement powder and located in the collecting box is located under the fine screen, and a collecting box located in the collecting box is located under the fine aggregate screen, The left side in mud powder chamber is used for collecting the thin aggregate chamber of fine aggregate, the left side in thin aggregate chamber is equipped with and is located the thick aggregate chamber in the collecting box.