CN111558418A - Building stones environmental protection extrusion equipment - Google Patents

Abstract

The invention relates to extrusion equipment, in particular to stone environment-friendly extrusion equipment which comprises a power pressurizing mechanism, an extrusion box mechanism and a feeding mechanism, wherein the equipment can extrude and crush materials, can remove dust, can increase the dust removal effect and reduce the extrusion crushing pressure, and can smoothly discharge materials.

Description

Building stones environmental protection extrusion equipment

Technical Field

The invention relates to extrusion equipment, in particular to environment-friendly stone extrusion equipment.

Background

In the crushing of building stones, the crushing of bold material is unobstructed to get into jaw breaker again after the processing of pre-crushing, just can satisfy the feeding size of next link breaker through two-step processing, can make efficiency reduce like this, and increases the process complexity, so designed this kind of building stones environmental protection extrusion equipment.

Disclosure of Invention

The invention mainly solves the technical problem of providing stone environment-friendly extrusion equipment which can extrude and crush materials, remove dust, reduce extrusion crushing pressure while improving dust removal effect and discharge materials smoothly.

In order to solve the technical problems, the invention relates to extrusion equipment, in particular to stone environment-friendly extrusion equipment which comprises a power pressurizing mechanism, an extrusion box mechanism and a feeding mechanism, wherein the equipment can extrude and crush materials, can remove dust, can increase the dust removal effect, simultaneously reduce the extrusion crushing pressure, and can smoothly discharge materials.

The power pressurizing mechanism is connected with the extrusion box mechanism, the power pressurizing mechanism is connected with the feeding mechanism, and the extrusion box mechanism is connected with the feeding mechanism.

As a further optimization of the technical scheme, the power pressurizing mechanism of the environment-friendly stone extrusion equipment comprises a supporting leg frame, a hydraulic cylinder seat, a hydraulic cylinder, a piston rod, a cross groove, a moving seat, a pulley with a shaft, a pulley seat, a sliding rod, a spring, a sliding matching hole, a hinging seat, a hinging arm, a limiting bulge, an inlet port, a sliding door, a sliding block, a squeezing seat with a rod, a ventilating hole, a platform, a gear, a bearing seat I, a hole plate, a connecting shaft, a reversing gear and a cross sliding block, wherein the supporting leg frame is connected with the platform, the platform is connected with the hydraulic cylinder seat, the hydraulic cylinder seat is connected with the hydraulic cylinder, the hydraulic cylinder is connected with the piston rod, the piston rod is connected with the moving seat, the moving seat is connected with the cross groove in a sliding manner, the cross groove is arranged on the platform, the moving seat is in contact with the pulley with the shaft, and the, pulley holder links to each other with the slide bar, the spring housing is on the slide bar, slide bar and sliding fit hole sliding connection, the sliding fit hole sets up on the platform, the slide bar links to each other with articulated seat, articulated seat is articulated mutually with the articulated arm, the articulated arm is articulated mutually with the sliding door, be equipped with the inlet port on the sliding door, spacing arch sets up on removing the seat, be equipped with the slider on the sliding door, band rod extrusion seat links to each other with removing the seat, be equipped with the ventilation hole on the band rod extrusion seat, the gear links to each other with the connecting axle, the connecting axle links to each other with reversing gear, the connecting axle is connected for the bearing with bearing frame I's connected mode, bearing frame I.

As a further optimization of the technical scheme, the extrusion box mechanism of the environment-friendly stone extrusion equipment comprises a supporting leg seat I, a crushing box body, a filtering plate with a handle, a sliding groove, an air box, a wind wheel motor, a coupler, a bearing seat II, a wind wheel shaft, a sliding groove I, an inlet port I, a toothed bar seat, a bulge I, a stepped sliding limiting rod, a perforated seat I, a stepped sliding limiting rod I, a crushing outlet, an air outlet I, a wind wheel and a crushing sliding matching hole, wherein the supporting leg seat I is connected with the crushing box body, the crushing box body is connected with a platform, the filtering plate with the handle is connected with the sliding groove in a sliding manner, the sliding groove is arranged on the air box, the air box is connected with the crushing box body, the air box is connected with the wind wheel motor, the wind wheel motor is connected with the wind wheel shaft through the coupler, the bearing seat II is arranged on the, wind wheel axle links to each other with the wind wheel, spout I sets up on smashing the case body, spout I and slider sliding connection, inlet port I sets up on smashing the case body, be equipped with protruding I on the tooth strip seat, take tooth strip seat and the ladder slide the gag lever post and link to each other, ladder slide the gag lever post and band hole board sliding connection, foraminiferous seat I links to each other with smashing the case body, foraminiferous seat I slides gag lever post I sliding connection with the ladder, ladder slide gag lever post I links to each other with taking tooth strip seat, it sets up on smashing the case body to smash the export, bearing frame II sets up on the bellows, crushing sliding fit hole sets up at smashing the case body, take pole extrusion seat and crushing sliding fit hole sliding connection.

As a further optimization of the technical scheme, the feeding mechanism of the environment-friendly stone extrusion equipment comprises a base, a vibration base, a sliding rod a, a vibration spring, a connecting plate, a vibration sliding hole, a vibration hopper and an arc bulge, wherein the base is connected with a supporting leg frame, the base is connected with a supporting leg seat I, the base is connected with the vibration base, the vibration base is connected with the sliding rod a, the sliding rod a is connected with the connecting plate, the vibration spring is sleeved on the sliding rod a, the vibration spring abuts against the vibration base and the vibration hopper, the sliding rod a is in sliding connection with the vibration sliding hole, the vibration sliding hole is formed in the vibration hopper, the arc bulge is formed in the vibration hopper, and the toothed bar seat is in contact with the vibration hopper.

As a further optimization of the technical scheme, the size of the inlet and the size of the inlet I of the environment-friendly stone extrusion equipment are equal.

As a further optimization of the technical scheme, the cross sliding block of the environment-friendly stone extrusion equipment is provided with teeth meshed with the reversing gear.

The environment-friendly stone extrusion equipment has the beneficial effects that:

according to the environment-friendly stone extrusion equipment, the equipment can extrude and crush materials, the equipment can remove dust, the equipment can increase the dust removal effect and reduce the extrusion crushing pressure, and the equipment can discharge materials smoothly.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first schematic structural view of an environmentally friendly stone extrusion apparatus according to the present invention.

FIG. 2 is a schematic structural diagram of an environment-friendly stone crushing apparatus according to the present invention.

Fig. 3 is a third schematic structural view of an environment-friendly stone extrusion apparatus according to the present invention.

Fig. 4 is a first structural schematic diagram of a power pressurizing mechanism 1 of the environment-friendly stone extrusion equipment of the invention.

Fig. 5 is a schematic structural diagram of a power pressurizing mechanism 1 of the environment-friendly stone extrusion equipment of the invention.

Fig. 6 is a third schematic structural diagram of the power pressurizing mechanism 1 of the environment-friendly stone extrusion equipment of the invention.

Fig. 7 is a fourth schematic structural view of the power pressurizing mechanism 1 of the environment-friendly stone crushing device of the invention.

Fig. 8 is a fifth schematic structural view of the power pressurizing mechanism 1 of the environment-friendly stone crushing device of the invention.

Fig. 9 is a first structural schematic diagram of the extrusion box mechanism 2 of the environment-friendly stone extrusion device of the invention.

Fig. 10 is a second schematic structural diagram of the extrusion box mechanism 2 of the environment-friendly stone extrusion device of the invention.

Fig. 11 is a third schematic structural diagram of the extrusion box mechanism 2 of the environment-friendly stone extrusion device of the invention.

Fig. 12 is a first structural schematic diagram of a feeding mechanism 3 of the environment-friendly stone extrusion equipment.

Fig. 13 is a second structural schematic diagram of the feeding mechanism 3 of the environment-friendly stone extrusion equipment of the invention.

Fig. 14 is a third schematic structural view of the feeding mechanism 3 of the environment-friendly stone extrusion device of the invention.

In the figure: a power pressurizing mechanism 1; a leg frame 1-1; 1-2 of a hydraulic cylinder seat; 1-3 of a hydraulic cylinder; a piston rod 1-4; 1-5 of a cross groove; 1-6 of a movable seat; pulley 1-7 with shaft; 1-8 pulley seats; 1-9 slide bars; 1-10 parts of spring; 1-11 of a sliding fit hole; hinge seats 1-12; articulated arms 1-13; 1-14 parts of limiting protrusions; access ports 1-15; sliding doors 1 to 16; 1-17 of a slide block; 1-18 of a belt rod extrusion seat; vent 1-19; 1-20 of a platform; gears 1-21; bearing seats I1-22; 1-23 parts of a perforated plate; connecting shafts 1-24; 1-25 of a reversing gear; 1-26 of a crosshead shoe; a squeezing box mechanism 2; a leg seat I2-1; 2-2 parts of a crushing box body; 2-3 of a filter plate with a handle; 2-4 of a sliding groove; 2-5 of an air box; 2-6 of a wind wheel motor; 2-7 of a coupler; bearing seat II 2-8; 2-9 parts of a wind wheel shaft; a chute I2-10; inlet port I2-11; 2-12 of a rack seat; the bulge I2-13; 2-14 of a stepped sliding limiting rod; perforated base I2-15; a stepped sliding limiting rod I2-16; a crushing outlet 2-17; an air outlet I2-18; 2-19 of wind wheel; crushing the sliding fit hole 2-20; a feeding mechanism 3; a base 3-1; vibrating the base 3-2; a slide bar A3-3; 3-4 of a vibration spring; 3-5 of a connecting plate; 3-6 of a vibration sliding hole; 3-7 of a vibrating hopper; and 3-8 of arc bulge.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, the invention relates to an extrusion device, and more specifically, to an environment-friendly extrusion device for stone materials, which includes a power pressurizing mechanism 1, an extrusion box mechanism 2, and a feeding mechanism 3, and is capable of extruding and crushing materials, removing dust, reducing extrusion crushing pressure while increasing dust removal effect, and discharging smoothly.

The power pressurizing mechanism 1 is connected with the extrusion box mechanism 2, the power pressurizing mechanism 1 is connected with the feeding mechanism 3, and the extrusion box mechanism 2 is connected with the feeding mechanism 3.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and the embodiment further describes the embodiment, where the power pressurizing mechanism 1 includes a leg frame 1-1, a hydraulic cylinder base 1-2, a hydraulic cylinder 1-3, a piston rod 1-4, a cross slot 1-5, a movable base 1-6, a pulley with a shaft 1-7, a pulley base 1-8, a slide rod 1-9, a spring 1-10, a slide-fit hole 1-11, a hinged base 1-12, a hinged arm 1-13, a limit protrusion 1-14, an inlet port 1-15, a slide door 1-16, a slide block 1-17, a squeezing base with a rod 1-18, a vent hole 1-19, a slide-11, 1-20 parts of platform, 1-21 parts of gear, I1-22 parts of bearing seat, 1-23 parts of perforated plate, 1-24 parts of connecting shaft, 1-25 parts of reversing gear, 1-26 parts of cross slide block, 1-1 parts of supporting leg frame connected with 1-20 parts of platform, 1-20 parts of platform connected with 1-2 parts of hydraulic cylinder seat, 1-2 parts of hydraulic cylinder seat connected with 1-3 parts of hydraulic cylinder, 1-3 parts of hydraulic cylinder connected with 1-4 parts of piston rod, 1-4 parts of piston rod connected with 1-6 parts of movable seat, 1-6 parts of movable seat connected with 1-26 parts of cross slide block, 1-26 parts of cross slide block connected with 1-5 parts of cross groove, 1-5 parts of cross groove arranged on 1-20 parts of platform, 1-6 parts of movable seat contacted with 1-7 parts of pulley with shaft, 1-7 parts of pulley connected with 1-8 parts of pulley seat in, pulley seats 1-8 are connected with sliding rods 1-9, springs 1-10 are sleeved on the sliding rods 1-9, the sliding rods 1-9 are slidably connected with sliding matching holes 1-11, the sliding matching holes 1-11 are arranged on platforms 1-20, the sliding rods 1-9 are connected with hinge seats 1-12, the hinge seats 1-12 are hinged with hinge arms 1-13, the hinge arms 1-13 are hinged with sliding doors 1-16, inlet openings 1-15 are arranged on the sliding doors 1-16, limit protrusions 1-14 are arranged on moving seats 1-6, sliding doors 1-16 are provided with sliding blocks 1-17, belt rod extrusion seats 1-18 are connected with moving seats 1-6, vent holes 1-19 are arranged on the belt rod extrusion seats 1-18, gears 1-21 are connected with connecting shafts 1-24, connecting shafts 1-24 are connected with reversing gears 1-25, connecting shafts 1-24 are connected with bearing seats I1-22 in a bearing mode, bearing seats I1-22 are connected with platforms 1-20, cross sliding blocks 1-26 are meshed with reversing gears 1-25, when a piston rod 1-4 pulls a moving seat 1-6, the moving seat 1-6 pushes a belt shaft pulley 1-7 upwards through the inclined plane of the moving seat 1-6, the belt shaft pulley 1-7 drives a pulley seat 1-8 to move upwards, the pulley seat 1-8 drives a sliding rod 1-9 to drive a hinged seat 1-12 to move upwards, the hinged seat 1-12 moves upwards to pull a sliding door 1-16 through a hinged arm 1-13, and thus the sliding door 1-16 drives an inlet port 1-15 to move, the inlet ports 1-15 are offset from the inlet ports I2-11, so that the feeding is stopped, the short-term squeezing pressure is reduced, and at the same time, the air flow is not discharged from the inlet ports I2-11 when moving upward during dust removal, so that dust is sucked away from the vent holes 1-19, thereby improving the dust removal effect.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and the present embodiment further describes the present embodiment, where the squeeze box mechanism 2 includes a leg base I2-1, a crush box body 2-2, a filter plate with handle 2-3, a slide groove 2-4, a wind box 2-5, a wind wheel motor 2-6, a coupling 2-7, a bearing base II2-8, a wind wheel shaft 2-9, a slide groove I2-10, an inlet port I2-11, a toothed bar base 2-12, a protrusion I2-13, a stepped slide limit rod 2-14, a perforated base I2-15, a stepped slide limit rod I2-16, a crush outlet 2-17, an outlet I2-18, a protrusion I2-13, a protrusion I, Wind wheel 2-19, crushing sliding matching hole 2-20, supporting leg seat I2-1 is connected with crushing box body 2-2, crushing box body 2-2 is connected with platform 1-20, filter plate 2-3 with handle is connected with sliding groove 2-4 in sliding mode, sliding groove 2-4 is arranged on wind box 2-5, wind box 2-5 is connected with crushing box body 2-2, wind box 2-5 is connected with wind wheel motor 2-6, wind wheel motor 2-6 is connected with wind wheel shaft 2-9 through coupling 2-7, bearing seat II2-8 is arranged on wind box 2-5, bearing seat II2-8 is connected with wind wheel shaft 2-9 in bearing mode, wind wheel shaft 2-9 is connected with wind wheel 2-19, sliding groove I2-10 is arranged on crushing box body 2-2, the sliding chute I2-10 is connected with the sliding block 1-17 in a sliding way, the inlet port I2-11 is arranged on the crushing box body 2-2, the toothed bar seat 2-12 is provided with a bulge I2-13, the toothed bar seat 2-12 is connected with the step sliding limiting rod 2-14, the step sliding limiting rod 2-14 is connected with the hole plate 1-23 in a sliding way, the hole seat I2-15 is connected with the crushing box body 2-2, the hole seat I2-15 is connected with the step sliding limiting rod I2-16 in a sliding way, the step sliding limiting rod I2-16 is connected with the toothed bar seat 2-12, the crushing outlet 2-17 is arranged on the crushing box body 2-2, the bearing seat II2-8 is arranged on the air box 2-5, the crushing sliding matching hole 2-20 is arranged on the crushing matching box body 2-2, the belt rod extrusion seat 1-18 is connected with the crushing sliding matching hole 2-20 in a sliding way, stone blocks are added from the inlet port 1-15 and then enter a cavity formed by the belt rod extrusion seat 1-18 and the crushing box body 2-2 through the inlet port I2-11, materials smaller than the distance between the belt rod extrusion seat 1-18 and the crushing box body 2-2 can directly fall down to reduce crushing pressure, materials larger than the distance can be clamped between the belt rod extrusion seat 1-18 and the crushing box body 2-2, hydraulic oil is injected through the hydraulic cylinder 1-3 to drive the piston rod 1-4 to retract into the hydraulic cylinder 1-3 to move, the piston rod 1-4 can pull the movable seat 1-6, the movable seat 1-6 can drive the belt rod extrusion seat 1-18 to move, the belt rod extrusion seat 1-18 can extrude the stone blocks, the crushed stone blocks fall downwards after being pressurized, hydraulic oil is reversely injected into the hydraulic cylinder 1-3, the rod-equipped extrusion seat 1-18 can reset under the driving of the oil pressure, the crushed stone blocks can fall down better, the wind wheel motor 2-6 operates to drive the coupler 2-7 to rotate, the coupler 2-7 can drive the wind wheel shaft 2-9 to rotate, the wind wheel shaft 2-9 can drive the wind wheel 2-19 to rotate, the wind wheel 2-19 rotates to form negative pressure, and under the driving of the negative pressure, dust generated in the extrusion crushing can be sucked into the wind box 2-5 from the vent holes 1-19 and then is discharged from the air outlet I2-18 after being filtered by the handle-equipped filter plate 2-3.

The fourth concrete implementation mode:

referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, the present embodiment further illustrates the present embodiment, in which the feeding mechanism 3 includes a base 3-1, a vibration base 3-2, a sliding rod A3-3, a vibration spring 3-4, a connecting plate 3-5, a vibration slide hole 3-6, a vibration bucket 3-7, and an arc protrusion 3-8, the base 3-1 is connected to a leg frame 1-1, the base 3-1 is connected to a leg base I2-1, the base 3-1 is connected to the vibration base 3-2, the vibration base 3-2 is connected to a sliding rod A3-3, the sliding rod A3-3 is connected to the connecting plate 3-5, the vibration spring 3-4 is sleeved on the sliding rod A3-3, the vibration spring 3-4 is abutted against the vibration base 3-2 and the vibration hopper 3-7, the sliding rod A3-3 is in sliding connection with the vibration sliding hole 3-6, the vibration sliding hole 3-6 is arranged on the vibration hopper 3-7, the arc bulge 3-8 is arranged on the vibration hopper 3-7, the toothed bar seat 2-12 is in contact with the vibration hopper 3-7, the crushed material can fall into the vibration hopper 3-7, the piston rod 1-4 can drive the movable seat 1-6 to reciprocate along with the forward and reverse alternate injection of hydraulic oil, the movable seat 1-6 can drive the cross slide block 1-26 to reciprocate linearly, the cross slide block 1-26 can drive the reversing gear 1-25 to reciprocate, the reversing gear 1-25 can drive the gear 1-21 to reciprocate through the connecting shaft 1-24, the gears 1-21 drive the toothed bar seats 2-12 to reciprocate, the toothed bar seats 2-12 drive the vibration hoppers 3-7 to repeatedly move downwards to compress the vibration springs 3-4 through the matching of the protrusions I2-13 and the circular arc protrusions 3-8 in the reciprocating motion, and then rebound under the elastic force action of the vibration springs 3-4, so that the vibration hoppers 3-7 can vibrate, stones can be vibrated from the vibration hoppers 3-7, and the materials can conveniently and smoothly move in the vibration hoppers 3-7.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and fig. 14, and the present embodiment further describes the first embodiment, in which the inlet ports 1 to 15 are equal in size to the inlet ports I2 to 11.

The sixth specific implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, and 14, and the present embodiment further describes the first embodiment in which the crosshead shoes 1 to 26 are provided with teeth that mesh with the reversing gears 1 to 25.

The working principle of the device is as follows: the equipment can extrude and crush materials, stone blocks are added from the inlet 1-15 and then enter a cavity formed by the belt rod extrusion seat 1-18 and the crushing box body 2-2 through the inlet I2-11, the material which is smaller than the distance between the belt rod extrusion seat 1-18 and the crushing box body 2-2 can directly fall down, the crushing pressure can be reduced, the material which is larger than the distance can be clamped between the belt rod extrusion seat 1-18 and the crushing box body 2-2, hydraulic oil is injected through the hydraulic cylinder 1-3 to drive the piston rod 1-4 to retract into the hydraulic cylinder 1-3 to move, the piston rod 1-4 can pull the movable seat 1-6, the movable seat 1-6 can drive the belt rod extrusion seat 1-18 to move, the belt rod extrusion seat 1-18 can extrude the stone blocks, the crushed stone blocks can fall down after pressure is applied, hydraulic oil is reversely injected into the hydraulic cylinders 1 to 3, and the extrusion seats with the rods 1 to 18 are reset under the driving of the oil pressure, so that crushed stones can fall down better; the equipment can remove dust, the shaft coupling 2-7 is driven to rotate by the operation of the wind wheel motor 2-6, the shaft coupling 2-7 can drive the wind wheel shaft 2-9 to rotate, the wind wheel shaft 2-9 can drive the wind wheel 2-19 to rotate, the wind wheel 2-19 can rotate to form negative pressure, and under the drive of the negative pressure, dust generated in extrusion crushing can be sucked into the wind box 2-5 from the vent holes 1-19 and then is discharged from the air outlet I2-18 after being filtered by the filter plate 2-3 with the handle; the equipment can increase the dust removal effect and reduce the extrusion crushing pressure, when the piston rod 1-4 pulls the movable seat 1-6, the movable seat 1-6 can push the belt shaft pulley 1-7 upwards through the self inclined plane of the movable seat 1-6, the belt shaft pulley 1-7 can drive the pulley seat 1-8 to move upwards, the pulley seat 1-8 can drive the slide rod 1-9 to drive the hinged seat 1-12 to move upwards, the hinged seat 1-12 moves upwards and pulls the sliding door 1-16 through the hinged arm 1-13, so that the sliding door 1-16 can drive the inlet port 1-15 to move, the inlet port 1-15 can be staggered with the inlet port I2-11, so that the feeding can be stopped, the short-time extrusion pressure is reduced, and meanwhile, when in dust removal, the air flow does not discharge from the inlet port I2-11 when moving upwards, thus, dust can be sucked from the air vents 1-19, and the dust removal effect can be improved; the device can discharge materials smoothly, the crushed materials can fall into the vibration hopper 3-7, the piston rod 1-4 can drive the moving seat 1-6 to reciprocate along with the forward and reverse alternate injection of hydraulic oil, the moving seat 1-6 can drive the cross slide block 1-26 to reciprocate linearly, the cross slide block 1-26 can drive the reversing gear 1-25 to reciprocate, the reversing gear 1-25 can drive the gear 1-21 to reciprocate through the connecting shaft 1-24, the gear 1-21 can drive the toothed bar seat 2-12 to reciprocate, the toothed bar seat 2-12 can drive the vibration hopper 3-7 to repeatedly move downwards to compress the vibration spring 3-4 through the matching of the bulge I2-13 and the arc bulge 3-8 during reciprocating motion, then rebounds under the elastic force of the vibration springs 3-4, so that the vibration buckets 3-7 vibrate, and stones are vibrated from the vibration buckets 3-7, and the materials can move smoothly in the vibration buckets 3-7.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (6)

1. The utility model provides a building stones environmental protection extrusion equipment, includes power loading system (1), extrusion case mechanism (2), feeding mechanism (3), its characterized in that: the power pressurizing mechanism (1) is connected with the extrusion box mechanism (2), the power pressurizing mechanism (1) is connected with the feeding mechanism (3), and the extrusion box mechanism (2) is connected with the feeding mechanism (3).

2. The environmentally friendly stone crushing apparatus as set forth in claim 1, wherein: the power pressurizing mechanism (1) comprises a supporting leg frame (1-1), a hydraulic cylinder seat (1-2), a hydraulic cylinder (1-3), a piston rod (1-4), a cross groove (1-5), a moving seat (1-6), a pulley (1-7) with a shaft, a pulley seat (1-8), a sliding rod (1-9), a spring (1-10), a sliding matching hole (1-11), a hinged seat (1-12), a hinged arm (1-13), a limiting protrusion (1-14), an inlet port (1-15), a sliding door (1-16), a sliding block (1-17), a squeezing seat (1-18) with a rod, a vent hole (1-19), a platform (1-20), a gear (1-21), a bearing seat I (1-22), The device comprises perforated plates (1-23), connecting shafts (1-24), reversing gears (1-25) and cross sliding blocks (1-26), wherein a leg support (1-1) is connected with a platform (1-20), the platform (1-20) is connected with a hydraulic cylinder base (1-2), the hydraulic cylinder base (1-2) is connected with a hydraulic cylinder (1-3), the hydraulic cylinder (1-3) is connected with a piston rod (1-4), the piston rod (1-4) is connected with a movable base (1-6), the movable base (1-6) is connected with the cross sliding blocks (1-26), the cross sliding blocks (1-26) are connected with cross grooves (1-5) in a sliding manner, the cross grooves (1-5) are arranged on the platform (1-20), the movable base (1-6) is contacted with pulley (1-7) with a shaft, the connection mode of the pulley (1-7) with a shaft and the pulley seat (1-8) is bearing connection, the pulley seat (1-8) is connected with the sliding rod (1-9), the spring (1-10) is sleeved on the sliding rod (1-9), the sliding rod (1-9) is connected with the sliding matching hole (1-11) in a sliding way, the sliding matching hole (1-11) is arranged on the platform (1-20), the sliding rod (1-9) is connected with the hinge seat (1-12), the hinge seat (1-12) is hinged with the hinge arm (1-13), the hinge arm (1-13) is hinged with the sliding door (1-16), the sliding door (1-16) is provided with an inlet (1-15), the limiting bulge (1-14) is arranged on the moving seat (1-6), the sliding door (1-16) is provided with a sliding block (1-17), the belt rod extrusion seat (1-18) is connected with the moving seat (1-6), the belt rod extrusion seat (1-18) is provided with vent holes (1-19), gears (1-21) are connected with connecting shafts (1-24), the connecting shafts (1-24) are connected with reversing gears (1-25), the connecting shafts (1-24) are connected with bearing seats I (1-22) in a bearing connection mode, the bearing seats I (1-22) are connected with platforms (1-20), and cross sliding blocks (1-26) are meshed with the reversing gears (1-25).

3. The environmentally friendly stone crushing apparatus as set forth in claim 1, wherein: the extrusion box mechanism (2) comprises a supporting leg seat I (2-1), a crushing box body (2-2), a filter plate with a handle (2-3), a sliding groove (2-4), an air box (2-5), a wind wheel motor (2-6), a coupler (2-7), a bearing seat II (2-8), a wind wheel shaft (2-9), a sliding groove I (2-10), an inlet port I (2-11), a toothed bar seat (2-12), a bulge I (2-13), a stepped sliding limiting rod (2-14), a perforated seat I (2-15), a stepped sliding limiting rod I (2-16), a crushing outlet (2-17), an air outlet I (2-18), a wind wheel (2-19) and a crushing sliding matching hole (2-20), the supporting leg seat I (2-1) is connected with the crushing box body (2-2), the crushing box body (2-2) is connected with the platform (1-20), the filter plate (2-3) with the handle is connected with the sliding groove (2-4) in a sliding way, the sliding groove (2-4) is arranged on the air box (2-5), the air box (2-5) is connected with the crushing box body (2-2), the air box (2-5) is connected with the wind wheel motor (2-6), the wind wheel motor (2-6) is connected with the wind wheel shaft (2-9) through the coupler (2-7), the bearing seat II (2-8) is arranged on the air box (2-5), the connection mode of the bearing seat II (2-8) and the wind wheel shaft (2-9) is bearing connection, the wind wheel shaft (2-9) is connected with the wind wheel (2-19), the chute I (2-10) is arranged on the crushing box body (2-2), the chute I (2-10) is connected with the sliding block (1-17) in a sliding way, the inlet port I (2-11) is arranged on the crushing box body (2-2), the toothed bar seat (2-12) is provided with a bulge I (2-13), the toothed bar seat (2-12) is connected with the stepped sliding limiting rod (2-14), the stepped sliding limiting rod (2-14) is connected with the perforated plate (1-23) in a sliding way, the perforated seat I (2-15) is connected with the crushing box body (2-2), the perforated seat I (2-15) is connected with the stepped sliding limiting rod I (2-16) in a sliding way, the stepped sliding limiting rod I (2-16) is connected with the toothed bar seat (2-12), the crushing outlet (2-17) is arranged on the crushing box body (2-2), the bearing seat II (2-8) is arranged on the air box (2-5), the crushing sliding fit hole (2-20) is arranged on the crushing box body (2-2), and the extrusion seat with the rod (1-18) is in sliding connection with the crushing sliding fit hole (2-20).

4. The environmentally friendly stone crushing apparatus as set forth in claim 1, wherein: the feeding mechanism (3) comprises a base (3-1), a vibration base (3-2), a sliding rod A (3-3), a vibration spring (3-4), a connecting plate (3-5), a vibration sliding hole (3-6), a vibration hopper (3-7) and an arc protrusion (3-8), wherein the base (3-1) is connected with a supporting leg frame (1-1), the base (3-1) is connected with a supporting leg seat I (2-1), the base (3-1) is connected with the vibration base (3-2), the vibration base (3-2) is connected with the sliding rod A (3-3), the sliding rod A (3-3) is connected with the connecting plate (3-5), the vibration spring (3-4) is sleeved on the sliding rod A (3-3), and the vibration spring (3-4) abuts against the vibration base (3-2), On the vibration bucket (3-7), a slide rod A (3-3) is connected with a vibration slide hole (3-6) in a sliding mode, the vibration slide hole (3-6) is arranged on the vibration bucket (3-7), an arc bulge (3-8) is arranged on the vibration bucket (3-7), and a rack seat (2-12) is in contact with the vibration bucket (3-7).

5. The environmentally friendly stone crushing apparatus as set forth in claim 2 or 3, wherein: the inlet openings (1-15) are equal to the inlet openings I (2-11) in size.

6. The environmentally friendly stone crushing apparatus as set forth in claim 2, wherein: the cross sliding blocks (1-26) are provided with teeth meshed with the reversing gears (1-25).

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