CN112536082A

CN112536082A - Double-station stone crushing device for building construction

Info

Publication number: CN112536082A
Application number: CN202011325472.6A
Authority: CN
Inventors: 刘玉峰; 何威潼
Original assignee: Wenzhou Tailewei Engineering Design Co ltd
Current assignee: Jiangmen Jianjun Building Materials Co ltd
Priority date: 2020-11-24
Filing date: 2020-11-24
Publication date: 2021-03-23
Anticipated expiration: 2040-11-24
Also published as: CN112536082B

Abstract

The invention relates to a double-station stone crushing device for building construction, which relates to the technical field of crushing cabins and solves the problems of low working efficiency and complex sieve plate structure of the crushing cabins, and comprises a top seat, a crushing cabin mechanism, a driving seat mechanism, a driven seat mechanism, a gear mechanism and a flow cabin, wherein the bottom of the top seat is provided with a bottom frame, the front top of the top seat is provided with a channel, a bidirectional screw rod is arranged in the channel through a bearing seat, the right side of the top seat is provided with a motor for driving the bidirectional screw rod to rotate, the bottom of the crushing cabin is provided with an inclined sieve plate, the two sieve plates are connected to the crushing cabin in a trial manner through a crank rod and a gear mechanism in a linkage manner, so that when the two crushing cabins move inwards, the two sieve plates can be driven to move according to a fluctuating type sieve material, stone falling on the sieve plates can be screened again, and, therefore, the vibrating motor does not need to be arranged at the bottom when the sieve plate moves, the sieving structure is simpler, and the design is ingenious.

Description

Double-station stone crushing device for building construction

Technical Field

The invention relates to the technical field of stone crushers for building construction, in particular to a double-station stone crushing device for building construction.

Background

During construction, the wall surface is usually applied to broken stone blocks, such as granite-type broken stone blocks and the like, and the broken stone blocks are coagulated on the wall surface along with concrete or cement, so that the strength of the wall body can be improved, the wall surface has the effect of improving the aesthetic feeling of the wall surface, and the wall surface looks stereoscopic, so that the wall surface is widely applied.

When the crushed aggregates machine is broken with bold nature stone, need broken great stone for crushing roller intensity of labour grow reduces life, and the stone after the breakage is more or less moreover, and size uniformity is relatively poor, need add when the sieve material ejection of compact of installation moreover and establish vibrating motor on the sieve, still can reduce the life of motor during the sieve vibration, and during the broken building stones of simplex position formula crushed aggregates cabin, work efficiency is lower.

Disclosure of Invention

In view of the above, the present invention aims to provide a double-station stone breaking device for building construction to solve the above problems.

The technical scheme of the invention is as follows: the double-station stone crushing device for building construction comprises a top seat, a crushing cabin mechanism, a driving seat mechanism, a driven seat mechanism, a gear tooth mechanism and a flow cabin, wherein the bottom of the top seat is provided with an underframe, the front top of the top seat is provided with a channel, a bidirectional screw rod is arranged in the channel through a bearing seat, the right side of the top seat is provided with a motor for driving the bidirectional screw rod to rotate, the crushing cabin mechanism is arranged at a left position and a right position, and the two crushing cabin mechanisms are arranged on left side threads and right side threads of the bidirectional screw rod through bottom threaded holes so that the two crushing cabin mechanisms can move left and right;

the crushing cabin mechanism comprises a moving seat arranged on the bidirectional screw rod and a crushing cabin fixed on the inner side of the moving seat, a leakage groove is formed in the bottom of the crushing cabin, a crushing mechanism is arranged on the top surface of the moving seat, a crushing rod arranged at the inner end of the crushing mechanism extends into the crushing cabin, and the moving seat drives the crushing mechanism to synchronously move;

the driving seat mechanism is arranged on the right crushing cabin through a sliding rail, the driven seat mechanism is arranged on the left crushing cabin through a sliding rail, and the driving seat mechanism and the driven seat mechanism form extrusion when moving inwards along with the two crushing cabins and slide in the two crushing cabins;

the flow cabin is welded on the inner side of the bottom frame and is located at the bottom of the crushing cabin mechanism, the sieve plate is installed in the flow cabin through a rotating shaft, the gear tooth mechanism is arranged between the sieve plate and the crushing cabin, the crushing cabin drives the sieve plate to move in an up-and-down type screening mode through the gear tooth mechanism during displacement, the bottom of the flow cabin is further provided with a collection cabin, and the collection cabin and the flow cabin form a discharge material and are communicated with each other.

Preferably, the method comprises the following steps: the driving seat mechanism comprises a first pressing seat sliding in the right crushing cabin through a sliding rail and a welding rod welded on the inner end face of the first pressing seat.

Preferably, the method comprises the following steps: driven seat mechanism includes that the second that slides in the garrulous cabin of left side through the slide rail presses the seat and sets up the guide hole on the seat is pressed to the second, and first pressure seat stretches into in the guide hole through the welding pole.

Preferably, the method comprises the following steps: the inner end faces of the first pressing seat and the second pressing seat are of an array rectangular block structure, and the welding rod and the guide hole are arranged on the rectangular block.

Preferably, the method comprises the following steps: the bottom of the two crushing cabins is provided with a flow cabin, the inner end faces of the left flow cabin and the right flow cabin are respectively provided with a first spring rod and a second spring rod, the top ends of the first spring rod and the second spring rod are welded with springs and are respectively connected onto a first pressure seat and a second pressure seat, and the top rod sections of the first spring rod and the second spring rod extend into the first pressure seat and the second pressure seat so that the first pressure seat and the second pressure seat can elastically reset outwards after moving inwards.

Preferably, the method comprises the following steps: gear teeth mechanism installs gear, the crank rod that is fixed in on the gear and welds in the footstock inner frame and with gear drive engaged with pinion rack in the preceding terminal surface of garrulous cabin including rotating, the bottom swivelling joint of crank rod is on the sieve.

Preferably, the method comprises the following steps: the sieve is installed on the stream cabin through the pivot to be outer slope setting down, one row of synchronizing bar is installed to the bottom surface of removal seat, and the synchronizing bar bottom contacts on the inclined plane of sieve.

Preferably, the method comprises the following steps: the synchronous rod is an elastic rod consisting of a spring and a scraping rod.

The technical effects of the invention are mainly reflected in the following aspects:

1. the mode that slides about adopting is provided with two broken cabins at the top to the corresponding two sets of crushing mechanisms that are provided with have constituted the broken structure of this device top duplex position formula, can drop into less graininess stone, and quick breakage recycles the little graininess ore of abandonment, and crushing speed is fast, simple structure, long service life, and work efficiency.

2. The inner side frames of the two crushing cabins are designed into action extrusion type, the two pressure seats are butted together in a sliding and inserting mode, when the two crushing cabins move inwards, the inner crushing stones can be pushed towards one side, in the pushing process, the stones can be turned, so that the shape of the stones is more regular after the stones are crushed again, the size and the size of the stones are not large, and the quality of the broken stones is improved.

3. All still be provided with gear mechanism in two garrulous cabin fronts, be equipped with the sieve of tilting in garrulous cabin bottom, two sieves trial connection on the garrulous cabin through the square of crank lever and gear mechanism linkage, consequently two garrulous cabins still can drive two sieves and expect the action according to the formula sieve of fluctuation when moving inwards, so that the building stones that fall on the sieve screen once more, the action that the sieve was accomplished the fluctuation and is moved and form when moving because of needs stirring because of two garrulous cabins, consequently, need not install vibrating motor in the bottom during the sieve moves, sieve dynamic structure is simpler, design benefit.

Drawings

FIG. 1: the three-dimensional structure of the invention is shown schematically;

FIG. 2: the invention is a schematic structural diagram of a front view plane drawn from figure 1;

FIG. 3: the invention is a structural schematic diagram of a left view plane which is drawn from figure 2;

FIG. 4: the invention is drawn from figure 2, part A is a schematic diagram of the internal structure after being cut;

FIG. 5: the invention is a structural schematic diagram of a top view angle;

FIG. 6: the invention is drawn from the enlarged structure diagram of part B of FIG. 5;

FIG. 7: the bottom view angle schematic diagram of the invention;

fig. 8 and 9: the invention is drawn from figure 1 in a schematic view of a rotational angle;

fig. 10 is a schematic view of the internal structure of the present invention cut in three-dimensional view.

Description of the main reference numerals:

the device comprises a top seat-1, a crushing mechanism-2, a crushing rod-3, an underframe-4, a bearing seat-5, a bidirectional screw-6, a crushing cabin mechanism-7, a moving seat-701, a synchronizing rod-70101, a crushing cabin-702, a leakage groove-703, a motor-8, a driving seat mechanism-9, a first pressing seat-901, a welding rod-902, a driven seat mechanism-10, a second pressing seat-1001, a guide hole-1002, a first spring rod-11, a second spring rod-12, a gear tooth mechanism-13, a gear-1301, a crank rod-toothed plate-1302, a flow cabin-14, a sieve plate-15 and a collection cabin-16.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying drawings 1-10 to make the technical solution of the present invention easier to understand and grasp.

The double-station stone breaking device for building construction comprises a top seat 1, a crushing cabin mechanism 7, a driving seat mechanism 9, a driven seat mechanism 10, a gear tooth mechanism 13 and a flow cabin 14, wherein the bottom of the top seat 1 is provided with an underframe 4, the front top of the top seat 1 is provided with a channel, a bidirectional screw 6 is arranged in the channel through a bearing seat 5, the right side of the top seat 1 is provided with a motor 8 for driving the bidirectional screw 6 to rotate, the crushing cabin mechanism 7 is arranged at a left position and a right position, the two crushing cabin mechanisms 7 are arranged on the left side thread and the right side thread of the bidirectional screw 6 through bottom threaded holes, so that the two crushing cabin mechanisms 7 can move left and right, as shown in figure 1, each crushing cabin mechanism 7 comprises a moving seat 701 arranged on the bidirectional screw 6 and a crushing cabin 702 fixed on the inner side of the moving seat 701, the bottom of each crushing cabin 702 is provided with a leakage groove 703, the top surface, in the prior art, the prior art is not described in detail, the installed crushing rod 3 at the inner end of the crushing mechanism 2 extends into the crushing cabin 702, the movable seat 701 drives the crushing mechanism 2 to synchronously move, when the crushing mechanism is actually used, stone is put into the two crushing cabins 702, the crushing rod 3 drives the extrusion plate to press down in the crushing cabin 702 when the crushing mechanism 2 works in a power-on mode, and the stone is crushed again, the double-station crushing mode improves the working efficiency, and meanwhile, when the crushing mechanism is actually used, the two crushing cabins 702 can realize opposite or reverse actions due to the influence of the bidirectional screw 6, so that the crushing cabin 702 can achieve the purpose of crushing and swinging at the same time, and therefore, the stone in the cabin can roll, and the stone can be crushed better again.

The driving seat mechanism 9 is arranged on the right-side crushing cabin 702 through a sliding rail, the driven seat mechanism 10 is arranged on the left-side crushing cabin 702 through a sliding rail, the driving seat mechanism 9 and the driven seat mechanism 10 form extrusion when the two crushing cabins 702 move inwards and move in the two crushing cabins 702 in a sliding manner, the driving seat mechanism 9 and the driven seat mechanism 10 form a movable blocking surface positioned on the inner sides of the two crushing cabins 702, the driving seat mechanism 9 comprises a first press seat 901 sliding in the right-side crushing cabin 702 through a sliding rail and a welding rod 902 welded on the inner end surface of the first press seat 901, the driven seat mechanism 10 comprises a second press seat 1001 sliding in the left-side crushing cabin 702 through a sliding rail and a guide hole 1002 arranged on the second press seat 1001, the first press seat 901 extends into the guide hole 1002 through the welding rod, when in actual use, the electrified motor 8 drives the bidirectional screw rod 6 to rotate, so that the two crushing cabins 702 arranged on the two side threads of the bidirectional screw rod 6 move in opposite directions, and after the first pressure seat 901 and the second pressure seat 1001 are contacted, extrusion is formed, the first pressure seat and the second pressure seat are both extruded towards the interior of the crushing cabin 702, stone in the crushing cabin 702 is forced to turn over due to the pushing reason, when the two mechanisms move inwards, the stone in the crushing cabin can be pushed again to turn over, and the aim of better crushing of the stone is further achieved.

The flow cabin 14 is welded on the inner side of the underframe 4 and is located at the bottom of the crushing cabin mechanism 7, the sieve plate 15 is installed in the flow cabin 14 through a rotating shaft, the gear tooth mechanism 13 is arranged between the sieve plate 15 and the crushing cabin 702, the crushing cabin 702 drives the sieve plate 15 to move up and down through the gear tooth mechanism 13 when moving, the gear tooth mechanism 13 comprises a gear 1301 rotatably installed on the front end surface of the crushing cabin 702, a crank rod 1302 fixed on the gear 1301 and a toothed plate 1303 welded on the inner frame of the top seat 1 and engaged with the gear 1301 in a transmission manner, the bottom end of the crank rod 1302 is rotatably connected to the sieve plate 15, when the crushing cabin 702 moves left and right, the gear 1301 is driven to move synchronously, the gear 1301 is engaged with the toothed plate 1303, the gear 1301 is forced to rotate, the rotating gear 1301 drives the sieve plate 15 to move up and down through the crank rod 1302 to form a vibration effect, of course, when the motor 8 rotates, the crushing cabin 702 moves in the opposite direction, (the motor 8 is the existing electrifying and controlling technology, which is not described in detail herein) screens the crushed stone falling on the sieve plate 15, so as to force the dust or fine particles in the stone to be uniformly discharged from the collecting cabin 16, the qualified stone is directly discharged from the sieve plate 15, and the power for the action of the sieve plate 15 comes from the left and right movement of the two crushing cabins 702, so that the sieve plate 15 can be driven to move in a linkage manner when the two crushing cabins 702 shake and turn over the stone, therefore, the structural design is ingenious, the vibrating motor is not needed to be additionally arranged at the bottom of the sieve plate 15, the structure is simple, the maintenance is convenient, in order to improve the functionality, when the crushing cabins 702 are used, the structure is more reasonable, and the work is expanded when the crushing cabins move left and right, therefore, a row of synchronizing rods 70101 is arranged on the bottom surface of the moving seat 701, the bottom ends of the synchronizing rods 70101 are in contact with the inclined surface of the sieve plate 15, the synchronizing rods 70, the scraper type material turning device can also achieve the aim of scraping and turning over stones during material screening and discharging, so that the stones can be screened downwards better from small particles when screened on the screen plate 15, and the screened stones are discharged outwards from the collecting cabin 16.

And because the inner end surfaces of the left and right flow chambers 14 are respectively provided with the first spring rod 11 and the second spring rod 12, the welding springs at the top ends of the first spring rod 11 and the second spring rod 12 are respectively connected to the first pressure seat 901 and the second pressure seat 1001, and the top rod sections of the first spring rod 11 and the second spring rod 12 extend into the first pressure seat 901 and the second pressure seat 1001, so that the first pressure seat 901 and the second pressure seat 1001 elastically reset outwards, and the structure is more reasonable.

The above are only typical examples of the present invention, and besides, the present invention may have other embodiments, and all the technical solutions formed by equivalent substitutions or equivalent changes are within the scope of the present invention as claimed.

Claims

1. Duplex position rubble device for construction, including footstock (1), garrulous cabin mechanism (7), initiative seat mechanism (9), driven seat mechanism (10), teeth of a cogwheel mechanism (13) and class room (14), the bottom of footstock (1) is provided with chassis (4), its characterized in that: the front top of the top seat (1) is provided with a channel, a bidirectional screw (6) is installed in the channel through a bearing seat (5), a motor (8) for driving the bidirectional screw (6) to rotate is installed on the right side of the top seat (1), the two cabin smashing mechanisms (7) are arranged on the left side and the right side, and the two cabin smashing mechanisms (7) are installed on the left side thread and the right side thread of the bidirectional screw (6) through bottom threaded holes so that the two cabin smashing mechanisms (7) can move left and right;

the crushing cabin mechanism (7) comprises a moving seat (701) arranged on the bidirectional screw (6) and a crushing cabin (702) fixed on the inner side of the moving seat (701), a leakage groove (703) is formed in the bottom of the crushing cabin (702), the crushing mechanism (2) is arranged on the top surface of the moving seat (701), a crushing rod (3) arranged at the inner end of the crushing mechanism (2) extends into the crushing cabin (702), and the moving seat (701) drives the crushing mechanism (2) to synchronously move;

the driving seat mechanism (9) is arranged on the right crushing cabin (702) through a sliding rail, the driven seat mechanism (10) is arranged on the left crushing cabin (702) through a sliding rail, and the driving seat mechanism (9) and the driven seat mechanism (10) form extrusion when moving inwards along with the two crushing cabins (702) and slide in the two crushing cabins (702);

flow cabin (14) and weld in chassis (4) inboard, and be located garrulous cabin mechanism (7) bottom, install sieve (15) through the pivot in flow cabin (14), teeth of a cogwheel mechanism (13) set up between sieve (15) and garrulous cabin (702), the action is moved through the undulant formula sieve of teeth of a cogwheel mechanism (13) drive sieve (15) during garrulous cabin (702) displacement, flow cabin (14) bottom still is provided with collection cabin (16), and collection cabin (16) and flow cabin (14) constitute to arrange the material and communicate with each other.

2. The double-station stone crushing device for building construction according to claim 1, characterized in that: the driving seat mechanism (9) comprises a first pressing seat (901) which slides in the right crushing cabin (702) through a sliding rail and a welding rod (902) welded on the inner end face of the first pressing seat (901).

3. The double-station stone crushing device for building construction according to claim 2, characterized in that: the driven seat mechanism (10) comprises a second pressing seat (1001) which slides in the left crushing cabin (702) through a sliding rail and a guide hole (1002) which is formed in the second pressing seat (1001), and the first pressing seat (901) extends into the guide hole (1002) through a welding rod (902).

4. The double-station stone crushing device for building construction according to claim 3, wherein: the inner end surfaces of the first pressing seat (901) and the second pressing seat (1001) are both of an array rectangular block structure, and the welding rod (902) and the guide hole (1002) are arranged on the rectangular block.

5. The double-station stone crushing device for building construction according to claim 3, wherein: the bottom of each of the two crushing cabins (702) is provided with a flow cabin (14), the inner end faces of the left flow cabin and the right flow cabin (14) are respectively provided with a first spring rod (11) and a second spring rod (12), the top ends of the first spring rod (11) and the second spring rod (12) are respectively connected to a first pressure seat (901) and a second pressure seat (1001), and the top rod sections of the first spring rod (11) and the second spring rod (12) extend into the first pressure seat (901) and the second pressure seat (1001) so that the first pressure seat (901) and the second pressure seat (1001) can elastically reset outwards after moving inwards.

6. The double-station stone crushing device for building construction according to claim 1, characterized in that: gear teeth mechanism (13) are including rotating gear (1301) of installing on garrulous cabin (702) preceding terminal surface, being fixed in crank rod (1302) on gear (1301) and weld in frame and with pinion rack (1303) of gear (1301) transmission meshing in footstock (1), the bottom of crank rod (1302) is changeed and is connect on sieve (15).

7. The double-station stone crushing device for building construction of claim 6, wherein: the sieve plate (15) is installed on the flow cabin (14) through a rotating shaft and is arranged in an outer-downward inclined mode, a row of synchronizing rods (70101) are installed on the bottom face of the moving seat (701), and the bottom ends of the synchronizing rods (70101) are in contact with the inclined face of the sieve plate (15).

8. The double-station stone crushing device for building construction according to claim 7, wherein: the synchronizing bar (70101) is an elastic bar composed of a spring and a scraping bar.