CN112237965A - Waste heat utilization environmental protection equipment - Google Patents

Abstract

The invention relates to the field of environmental protection, in particular to waste heat utilization environmental protection equipment. Can realize adjusting the crushing degree of the raw materials. The grinding device comprises a power assembly, a grinding assembly and an underframe assembly, and when raw materials are in contact with a grinding roller and a middle-end grinding disc, the generated damping effects are different, so that the rotating speed of the middle-end grinding disc is reduced, and further, the rotating speed of a middle-end driving frame is increased through the working principle of a differential mechanism, so that the grinding efficiency is conveniently improved; simultaneously, slide the push rod along the upper end cover for the degree that push rod extrusion middle-end pushed the spring changes, and then makes the raw materials crumb's that rolls formation between roller and the middle-end pressure rolling dish specification change, and then realizes the regulation to raw materials crushing degree.

Description

Waste heat utilization environmental protection equipment

Technical Field

The invention relates to the field of environmental protection, in particular to waste heat utilization environmental protection equipment.

Background

The waste heat utilization environmental protection equipment is a common equipment in the environmental protection field, but the function of the common waste heat utilization environmental protection equipment is single.

Disclosure of Invention

The invention aims to provide waste heat utilization environment-friendly equipment which can adjust the crushing degree of raw materials.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a waste heat utilization environmental protection equipment, includes power component, crushing unit, chassis subassembly, power component is connected with crushing unit, and crushing unit is connected with the chassis subassembly.

As a further optimization of the technical scheme, the invention relates to waste heat utilization environment-friendly equipment, which comprises a power bottom plate, a rack, an input motor, a middle end rotating rod I, a friction wheel I, a middle end transmission friction wheel, a middle end rotating rod, a hinged connecting rod I, an upper end rotor, a middle end frame, a friction wheel II, a friction wheel rotating rod II, a middle end rotating rod II, a clutch sliding rod I, a clutch rod II, a sliding frame I, a sliding frame II, a lower end clamping groove I, a middle end cross groove II, a lower end clamping groove II, an inner end spherical clamping groove, a middle end rectangular sliding rod, a spherical clamping rod pushing spring, a prismatic clamping rod I, a prismatic clamping rod pushing spring I, a prismatic clamping rod II and a prismatic clamping rod pushing spring II, wherein the rack is fixedly connected with the power bottom plate, the input motor is fixedly connected with the rack, the middle end rotating rod I is rotatably connected with the power bottom plate, the middle end rotating rod I is fixedly connected with an output shaft, a first friction wheel rotating rod is connected with a first middle end rotating rod in a sliding manner, the first friction wheel rotating rod is fixedly connected with a first friction wheel, the first friction wheel is in friction transmission with a first middle end transmission friction wheel, the middle end transmission friction wheel is connected with a middle end rectangular slider in a rotating manner, the middle end rotating rod is connected with a middle end transmission friction wheel in a rotating manner, a first hinge connecting rod is connected with the middle end rotating rod in a hinged manner, an upper end rotor is connected with the first hinge connecting rod in a sliding manner, the upper end rotor is connected with the middle end frame in a matched manner, the middle end frame is fixedly connected with the middle end frame, a second friction wheel is in friction transmission with the middle end transmission friction wheel, a second friction wheel is fixedly connected with a second friction wheel rotating rod, the second friction wheel rotating rod is connected with a second middle end rotating rod in a sliding manner, the second middle end rotating rod is connected with a power bottom plate in a rotating manner, the first clutch sliding rod is fixedly connected with the second middle end rotating, the first clutch rod is connected with the second clutch rod in a matching way, the second clutch rod is connected with the power bottom plate in a rotating way, the first carriage and the second carriage are connected with the power bottom plate in a sliding way, the first carriage is connected with the second middle-end rotating rod in a matching way, the first middle-end rotating rod is connected with the second carriage in a matching way, the first lower end clamping groove, the second middle-end cross groove and the second lower end clamping groove are all arranged on the power bottom plate, the second prismatic clamping rod is connected with the first carriage in a sliding way, the second prismatic clamping rod is connected with the second carriage in a matching way, the second prismatic clamping rod pushing spring is arranged between the second prismatic clamping rod and the first carriage, the first prismatic clamping rod is connected with the second lower end clamping groove in a matching way, the spherical clamping groove at the inner end is arranged at the inner end of the cross groove at the middle end, the spherical clamping rod is connected with the rectangular slider at the middle end in a sliding way, and the spherical clamping rod pushing spring is arranged, the spherical clamping rod is connected with the spherical clamping groove at the inner end in a matching way.

As a further optimization of the technical scheme, the invention relates to waste heat utilization environment-friendly equipment, which comprises an outer end sleeve, an upper end cover, a feeding port, a pressing rod clamping groove, an inner end spherical clamping rod II, an inner end spherical clamping rod push spring II, a slide rod I, a middle end push spring, a middle end driving frame, a rolling roller, a middle end rolling disc, a discharging hole I, a discharging hole II, a rotating sleeve I, a lower end rotating rod, a conical tooth I, a conical tooth II, a conical tooth III, a conical tooth IV, a conical tooth V, a conical tooth shaft I and a discharging rod, wherein the upper end cover is fixedly connected with the outer end sleeve, the feeding port is arranged on the upper end cover, the pressing rod is in sliding connection with the upper end cover, the pressing rod clamping groove is arranged on the pressing rod, the inner end spherical clamping rod II is in sliding connection with the upper end cover, the inner end spherical clamping rod push spring II is arranged between the inner end spherical clamping rod II and the upper end cover, the inner end spherical clamping rod is, a first sliding rod is connected with a pressing rod in a sliding manner, a middle-end push spring is connected with the first sliding rod in a sleeved manner, the first sliding rod is fixedly connected with a middle-end driving frame, the middle-end push spring is arranged between the pressing rod and the middle-end driving frame, a rolling roller is connected with the middle-end driving frame in a rotating manner, a middle-end rolling plate is fixedly connected with a first rotating sleeve, the first rotating sleeve is connected with an outer-end sleeve in a rotating manner, a lower-end rotating rod is connected with the middle-end driving frame in a sliding fit manner, a first discharge hole is formed in the middle-end rolling plate, a second discharge hole is formed in the outer-end sleeve, the discharge rod is fixedly connected with the outer-end sleeve, a first conical tooth is fixedly connected with the lower-end rotating rod, a second conical tooth is fixedly connected with the first rotating sleeve, the lower-end rotating rod is, the bevel gear II is in meshing transmission, the bevel gear V is in meshing transmission with the bevel gear III, the bevel gear shaft I is fixedly connected with the bevel gear V, and the clutch rod II is fixedly connected with the bevel gear shaft I.

According to the technical scheme, the environment-friendly equipment for utilizing the waste heat comprises an underframe body, a first support rod and a fixed boss, wherein the first support rod and the fixed boss are fixedly connected with the underframe body, a third bevel gear is rotatably connected with the first support rod, a power bottom plate is fixedly connected with the fixed boss, and an outer end sleeve is fixedly connected with the underframe body.

As a further optimization of the technical scheme, the waste heat utilization environmental protection equipment comprises an input motor external waste heat power generation module.

The waste heat utilization environmental protection equipment has the beneficial effects that:

according to the waste heat utilization environment-friendly equipment, when the raw materials are in contact with the rolling rollers and the middle-end rolling disc, the damping effects are different, so that the rotating speed of the middle-end rolling disc is reduced, the rotating speed of the middle-end driving frame is increased through the working principle of the differential mechanism, and the crushing efficiency is conveniently improved; simultaneously, slide the push rod along the upper end cover for the degree that push rod extrusion middle-end pushed the spring changes, and then makes the raw materials crumb's that rolls formation between roller and the middle-end pressure rolling dish specification change, and then realizes the regulation to raw materials crushing degree.

Drawings

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

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic view of the power assembly of the present invention;

FIG. 4 is a schematic structural diagram II of the power assembly of the present invention;

FIG. 5 is a third schematic structural view of the power assembly of the present invention;

FIG. 6 is a fourth schematic structural view of the power assembly of the present invention;

FIG. 7 is a first schematic view of the shredder assembly of the present invention;

FIG. 8 is a second schematic view of the shredder assembly of the present invention;

FIG. 9 is a third schematic view of the shredder assembly of the present invention;

figure 10 is a fourth schematic view of the size reduction assembly of the present invention;

fig. 11 is a schematic view of the undercarriage assembly configuration of the present invention.

In the figure: a power assembly 1; a power backplane 1-1; a frame 1-2; inputting a motor 1-3; a middle end rotating rod 1-4; 1-5 of a friction wheel rotating rod I; 1-6 parts of a first friction wheel; 1-7 middle-end transmission friction wheels; 1-8 middle end rotating rods; 1-9 of a first hinged connecting rod; 1-10 of an upper end rotor; middle end frames 1-11; 1-12 parts of a second friction wheel; a second friction wheel rotating rod 1-13; a middle end rotating rod II 1-14; 1-15 parts of a clutch sliding rod I; 1-16 of clutch lever; a second clutch lever 1-17; 1-18 of a first sliding frame; a second carriage 1-19; a first clamping groove at the lower end is 1-20; 1-21 parts of middle cross groove; a second clamping groove 1-22 at the lower end; 1-23 spherical clamping grooves at the inner ends; 1-24 middle-end rectangular sliders; 1-25 parts of a spherical clamping rod; 1-26 parts of a spherical clamping rod push spring; 1-27 of a prismatic clamping rod I; a prismatic clamping rod push spring 1-28; 1-29 parts of a prismatic clamping rod II; a prismatic clamping rod push spring II 1-30; a crushing assembly 2; an outer end sleeve 2-1; an upper end cover 2-2; a feeding port 2-3; pressing a rod 2-4; 2-5 of a pressing rod clamping groove; 2-6 of a spherical clamping rod II at the inner end; a second 2-7 push spring of the spherical clamping rod at the inner end; 2-8 sliding rods; a middle end push spring 2-9; 2-10 parts of a middle-end driving frame; 2-11 parts of a roller; 2-12 middle-end grinding discs; a first discharge hole 2-13; 2-14 parts of a discharge hole II; rotating the first sleeve 2-15; a lower rotating rod 2-16; 2-17 parts of a first bevel gear; 2-18 parts of a second bevel gear; 2-19 parts of bevel gear III; 2-20 parts of bevel gear; 2-21 parts of bevel gear five; 2-22 parts of a bevel gear shaft I; 2-23 parts of a discharging rod; a chassis assembly 3; a chassis body 3-1; 3-2 of a first support rod; and 3-3 of a fixed boss.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 11, and the waste heat utilization environmental protection device includes a power assembly 1, a pulverization assembly 2, and an underframe assembly 3, where the power assembly 1 is connected to the pulverization assembly 2, and the pulverization assembly 2 is connected to the underframe assembly 3.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-11, and the embodiment will be further described, where the power assembly 1 includes a power bottom plate 1-1, a frame 1-2, an input motor 1-3, a middle rotating rod 1-4, a friction wheel rotating rod 1-5, a friction wheel 1-6, a middle transmission friction wheel 1-7, a middle rotating rod 1-8, a hinge connecting rod 1-9, an upper end rotor 1-10, a middle frame 1-11, a friction wheel II 1-12, a friction wheel rotating rod II 1-13, a middle rotating rod II 1-14, a clutch sliding rod I1-15, a clutch rod I1-16, a clutch rod II 1-17, a carriage I-18, a carriage II 1-19, a lower end slot I1-20, a middle cross slot 1-21, a middle cross slot II 1-21, A lower end clamping groove II 1-22, an inner end spherical clamping groove 1-23, a middle end rectangular slider 1-24, a spherical clamping rod 1-25, a spherical clamping rod push spring 1-26, a prismatic clamping rod I1-27, a prismatic clamping rod push spring I1-28, a prismatic clamping rod II 1-29, a prismatic clamping rod push spring II 1-30, a rack 1-2 is fixedly connected with a power bottom plate 1-1, an input motor 1-3 is fixedly connected with the rack 1-2, a middle end rotating rod I1-4 is rotatably connected with the power bottom plate 1-1, a middle end rotating rod I1-4 is fixedly connected with an output shaft of the input motor 1-3, a friction wheel rotating rod I1-5 is slidably connected with a middle end rotating rod I1-4, a friction wheel rotating rod I1-5 is fixedly connected with a friction wheel I1-6, a friction wheel I1-6 is in friction transmission with a middle end transmission friction wheel 1-7, the middle end transmission friction wheel 1-7 is rotationally connected with the middle end rectangular slider 1-24, the middle end rotating rod 1-8 is rotationally connected with the middle end transmission friction wheel 1-7, the hinge connecting rod 1-9 is hinged with the middle end rotating rod 1-8, the upper end rotor 1-10 is slidably connected with the hinge connecting rod 1-9, the upper end rotor 1-10 is matched and connected with the middle end frame 1-11, the middle end frame 1-11 is fixedly connected with the middle end frame 1-11, the friction wheel II 1-12 is in friction transmission with the middle end transmission friction wheel 1-7, the friction wheel II 1-12 is fixedly connected with the friction wheel rotating rod II 1-13, the friction wheel rotating rod II 1-13 is slidably connected with the middle end rotating rod II 1-14, the middle end rotating rod II 1-14 is rotationally connected with the power bottom plate 1-1, the first clutch slide bar 1-15 is fixedly connected with the second middle end rotary bar 1-14, the first clutch slide bar 1-16 is connected with the first clutch slide bar 1-15 in a sliding manner, the first clutch slide bar 1-16 and the first clutch slide bar 1-15 are provided with springs A, the first clutch slide bar 1-16 is connected with the second clutch slide bar 1-17 in a matching manner, the second clutch slide bar 1-17 is connected with the power bottom plate 1-1 in a rotating manner, the first carriage 1-18 and the second carriage 1-19 are connected with the power bottom plate 1-1 in a sliding manner, the first carriage 1-18 is connected with the second middle end rotary bar 1-14 in a matching manner, the first middle end rotary bar 1-4 is connected with the second carriage 1-19 in a matching manner, the first lower end clamping groove 1-20, the first middle end cross groove 1-21 and the second lower end clamping groove 1-22 are all arranged on the power bottom plate 1-1, and the second, the prismatic clamping rod II 1-29 is connected with the lower end clamping groove II 1-22 in a matching mode, the prismatic clamping rod push spring II 1-30 is arranged between the prismatic clamping rod II 1-29 and the carriage I1-18, the prismatic clamping rod I1-27 is connected with the carriage II 1-19 in a sliding mode, the prismatic clamping rod I1-28 is arranged between the prismatic clamping rod I1-27 and the carriage II 1-19, the prismatic clamping rod I1-27 is connected with the lower end clamping groove II 1-22 in a matching mode, the inner end spherical clamping groove 1-23 is arranged at the inner end of the middle end cross groove 1-21, the spherical clamping rod 1-25 is connected with the middle end rectangular slider 1-24 in a sliding mode, the spherical clamping rod push spring 1-26 is arranged between the spherical clamping rod 1-25 and the middle end rectangular slider 1-24, and the spherical clamping rod 1-25 is connected with the inner end spherical clamping groove 1-23 in a matching mode.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1-11, and the crushing assembly 2 comprises an outer end sleeve 2-1, an upper end cover 2-2, a material inlet 2-3, a pressing rod 2-4, a pressing rod clamping groove 2-5, an inner end spherical clamping rod II 2-6, an inner end spherical clamping rod pushing spring II 2-7, a sliding rod I2-8, a middle end pushing spring 2-9, a middle end driving frame 2-10, a rolling roller 2-11, a middle end rolling disc 2-12, a discharging hole I2-13, a discharging hole II 2-14, a rotating sleeve I2-15, a lower end rotating rod 2-16, a cone tooth I2-17, a cone tooth II 2-18, a cone tooth III 2-19, a cone tooth IV 2-20, a cone tooth V2-21, A bevel gear shaft I2-22, a discharge rod 2-23, an upper end cover 2-2 fixedly connected with an outer end sleeve 2-1, a feeding port 2-3 arranged on the upper end cover 2-2, a press rod 2-4 slidably connected with the upper end cover 2-2, a press rod clamping groove 2-5 arranged on the press rod 2-4, an inner end spherical clamping rod II 2-6 slidably connected with the upper end cover 2-2, an inner end spherical clamping rod push spring II 2-7 arranged between the inner end spherical clamping rod II 2-6 and the upper end cover 2-2, an inner end spherical clamping rod II 2-6 matched and connected with the press rod clamping groove 2-5, a slide rod I2-8 slidably connected with the press rod 2-4, a middle end push spring 2-9 sleeved and connected with the slide rod I2-8, a slide rod I2-8 fixedly connected with a middle end driving frame 2-10, a middle end push spring 2-9 is arranged between a pressing rod 2-4 and a middle end driving frame 2-10, a rolling roller 2-11 is rotationally connected with the middle end driving frame 2-10, a middle end rolling plate 2-12 is fixedly connected with a rotating sleeve pipe 2-15, the rotating sleeve pipe 2-15 is rotationally connected with an outer end sleeve pipe 2-1, a lower end rotating rod 2-16 is connected with the middle end driving frame 2-10 in a sliding fit manner, a discharge hole I2-13 is arranged on the middle end rolling plate 2-12, a discharge hole II 2-14 is arranged on the outer end sleeve pipe 2-1, a discharge rod 2-23 is fixedly connected with the outer end sleeve pipe 2-1, a conical tooth I2-17 is fixedly connected with the lower end rotating rod 2-16, a conical tooth II 2-18 is fixedly connected with the rotating sleeve pipe I2-15, the lower end rotating rod 2-16 is rotationally connected with the rotating sleeve pipe I2-15, the bevel gear IV 2-20 is rotationally connected with the bevel gear III 2-19, the bevel gear IV 2-20 is in meshing transmission with the bevel gear I2-17 and the bevel gear II 2-18, the bevel gear V2-21 is in meshing transmission with the bevel gear III 2-19, the bevel gear shaft I2-22 is fixedly connected with the bevel gear V2-21, and the clutch rod II 1-17 is fixedly connected with the bevel gear shaft I2-22

The rotation of the second clutch rod 1-17 drives the first bevel gear shaft 2-22 to rotate, further drives the fifth bevel gear 2-21 to rotate through the first bevel gear shaft 2-22, further drives the third bevel gear 2-19 to rotate through the fifth bevel gear 2-21, further drives the fourth bevel gear 2-20 to rotate through the third bevel gear 2-19, and further drives the first bevel gear 2-17 through the fourth bevel gear 2-20; the bevel teeth II 2-18 rotate simultaneously, the lower rotating rods 2-16 are driven to rotate by the bevel teeth I2-17, the middle driving frames 2-10 are driven to rotate by the lower rotating rods 2-16, the rolling rollers 2-11 are driven to rotate by the middle driving frames 2-10, and the raw materials are simultaneously crushed by the contact of the rolling rollers 2-11 and the middle rolling discs 2-12; meanwhile, when the raw materials are in contact with the rolling rollers 2-11 and the middle-end rolling discs 2-12, the generated damping effects are different, so that the rotating speed of the middle-end rolling discs 2-12 is reduced, the rotating speed of the middle-end driving frames 2-10 is increased through the working principle of the differential mechanism, and the crushing efficiency is further improved conveniently; meanwhile, the pressing rod 2-4 slides along the upper end cover 2-2, so that the degree of the pressing rod 2-4 extruding the middle end push spring 2-9 is changed, the specification of raw material fragments formed between the grinding rollers 2-11 and the middle end grinding disc 2-12 is changed, and the grinding degree of the raw materials is adjusted; the crushed raw materials are discharged through the discharging rods 2-23, and then are conveniently collected.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 11, and the embodiment further describes the first embodiment, where the chassis assembly 3 includes a chassis body 3-1, a first support rod 3-2, and a fixing boss 3-3, the first support rod 3-2, the fixing boss 3-3 and the chassis body 3-1 are fixedly connected, a third bevel gear 2-19 and the first support rod 3-2 are rotatably connected, a power base plate 1-1 and the fixing boss 3-3 are fixedly connected, and an outer end sleeve 2-1 and the chassis body 3-1 are fixedly connected.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 11, and the present embodiment further describes the first embodiment, where the input motor 1 to 3 is an external waste heat power generation module.

The invention relates to a waste heat utilization environment-friendly device, which has the working principle that:

when the device is used, the waste heat power generation module externally connected with the input motor 1-3 generates power, the input motor 1-3 is driven to rotate, the middle rotating rod 1-4 is driven to rotate through the input motor 1-3, the friction wheel rotating rod 1-5 is driven to rotate through the middle rotating rod 1-4, the friction wheel 1-6 is driven to rotate through the friction wheel rotating rod 1-5, the middle transmission friction wheel 1-7 is driven to rotate through the friction wheel 1-6, the friction wheel II 1-12 is driven to rotate through the middle transmission friction wheel II 1-7, the friction wheel rotating rod II 1-13 is driven to rotate through the friction wheel II 1-12, and the middle rotating rod II 1-14 is driven to rotate through the friction wheel rotating rod II 1-13, the first clutch slide bar 1-15 is driven to rotate by the middle end rotating rod II 1-14, the first clutch slide bar 1-16 is driven to rotate by the first clutch slide bar 1-15, the second clutch slide bar 1-17 is driven to rotate by the first clutch slide bar 1-16, and power output is conveniently carried out by the second clutch slide bar 1-17; meanwhile, manually rotating the first hinged connecting rod 1-9, further driving the upper end rotor 1-10 to move through the first hinged connecting rod 1-9, simultaneously driving the middle end rotating rod 1-8 to move through the first hinged connecting rod 1-9, further driving the middle end transmission friction wheel 1-7 to move, further driving the middle end rectangular slider 1-24 to slide in the middle end cross groove 1-21 through the middle end transmission friction wheel 1-7, further enabling the transmission positions of the first friction wheel 1-6 and the second friction wheel 1-12 on the middle end transmission friction wheel 1-7 to change, and further enabling the rotation speed output through the second clutch rod 1-17 to change; putting raw materials to be crushed into the crushing assembly 2 through a feeding port 2-3, simultaneously, driving a first bevel gear shaft 2-22 to rotate by rotating a second clutch rod 1-17, further driving a fifth bevel gear 2-21 to rotate by driving the first bevel gear shaft 2-22, further driving a third bevel gear 2-19 to rotate by driving a third bevel gear 2-21, further driving a fourth bevel gear 2-20 to rotate by driving the third bevel gear 2-19, and further driving the first bevel gear 2-17 through the fourth bevel gear 2-20; the bevel teeth II 2-18 rotate simultaneously, the lower rotating rods 2-16 are driven to rotate by the bevel teeth I2-17, the middle driving frames 2-10 are driven to rotate by the lower rotating rods 2-16, the rolling rollers 2-11 are driven to rotate by the middle driving frames 2-10, and the raw materials are simultaneously crushed by the contact of the rolling rollers 2-11 and the middle rolling discs 2-12; meanwhile, when the raw materials are in contact with the rolling rollers 2-11 and the middle-end rolling discs 2-12, the generated damping effects are different, so that the rotating speed of the middle-end rolling discs 2-12 is reduced, the rotating speed of the middle-end driving frames 2-10 is increased through the working principle of the differential mechanism, and the crushing efficiency is further improved conveniently; meanwhile, the pressing rod 2-4 slides along the upper end cover 2-2, so that the degree of the pressing rod 2-4 extruding the middle end push spring 2-9 is changed, the specification of raw material fragments formed between the grinding rollers 2-11 and the middle end grinding disc 2-12 is changed, and the grinding degree of the raw materials is adjusted; the crushed raw materials are discharged through the discharging rods 2-23, and then are conveniently collected.

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 (5)

1. The utility model provides a waste heat utilization environmental protection equipment, includes power component (1), crushing unit (2), chassis subassembly (3), its characterized in that: the power assembly (1) is connected with the crushing assembly (2), and the crushing assembly (2) is connected with the chassis assembly (3).

2. The waste heat utilization environmental protection device according to claim 1, characterized in that: the power assembly (1) comprises a power bottom plate (1-1), a rack (1-2), an input motor (1-3), a middle-end rotating rod I (1-4), a friction wheel rotating rod I (1-5), a friction wheel I (1-6), a middle-end transmission friction wheel (1-7), a middle-end rotating rod (1-8), a hinged connecting rod I (1-9), an upper-end rotor (1-10), a middle-end frame (1-11), a friction wheel II (1-12), a friction wheel rotating rod II (1-13), a middle-end rotating rod II (1-14), a clutch sliding rod I (1-15), a clutch rod I (1-16), a clutch rod II (1-17), a sliding frame I (1-18), a sliding frame II (1-19), a lower end clamping groove I (1-20), A middle end cross slot (1-21), a lower end clamping slot II (1-22), an inner end spherical clamping slot (1-23), a middle end rectangular slider (1-24), a spherical clamping rod (1-25), a spherical clamping rod push spring (1-26), a prismatic clamping rod I (1-27), a prismatic clamping rod push spring I (1-28), a prismatic clamping rod II (1-29) and a prismatic clamping rod push spring II (1-30), wherein the frame (1-2) is fixedly connected with the power bottom plate (1-1), the input motor (1-3) is fixedly connected with the frame (1-2), a middle end rotating rod I (1-4) is rotatably connected with the power bottom plate (1-1), a middle end rotating rod I (1-4) is fixedly connected with an output shaft of the input motor (1-3), a friction wheel rotating rod I (1-5) is slidably connected with the middle end rotating rod I (1-4), a first friction wheel rotating rod (1-5) is fixedly connected with a first friction wheel (1-6), the first friction wheel (1-6) is in friction transmission with a middle-end transmission friction wheel (1-7), the middle-end transmission friction wheel (1-7) is in rotary connection with a middle-end rectangular slider (1-24), a middle-end rotating rod (1-8) is in rotary connection with a middle-end transmission friction wheel (1-7), a first hinged connecting rod (1-9) is hinged with the middle-end rotating rod (1-8), an upper-end rotor (1-10) is in sliding connection with the first hinged connecting rod (1-9), an upper-end rotor (1-10) is in matched connection with a middle-end frame (1-11), the middle-end frame (1-11) is fixedly connected with the middle-end frame (1-11), a second friction wheel (1-12) is in friction transmission with the middle-end transmission friction wheel (1-7), a friction wheel II (1-12) is fixedly connected with a friction wheel rotating rod II (1-13), the friction wheel rotating rod II (1-13) is connected with a middle end rotating rod II (1-14) in a sliding way, the middle end rotating rod II (1-14) is connected with a power bottom plate (1-1) in a rotating way, a clutch sliding rod I (1-15) is fixedly connected with the middle end rotating rod II (1-14), a clutch rod I (1-16) is connected with the clutch sliding rod I (1-15) in a sliding way, a spring A is arranged between the clutch rod I (1-16) and the clutch sliding rod I (1-15), the clutch rod I (1-16) is connected with the clutch rod II (1-17) in a matching way, the clutch rod II (1-17) is connected with the power bottom plate (1-1) in a rotating way, a sliding frame I (1-18) and a sliding frame II (1-19) are connected with the power bottom plate (1-1) in a, the first carriage (1-18) is connected with the second middle-end rotating rod (1-14) in a matching way, the first middle-end rotating rod (1-4) is connected with the second carriage (1-19) in a matching way, the first lower-end clamping groove (1-20), the cross groove (1-21) at the middle end and the second lower-end clamping groove (1-22) are all arranged on the power bottom plate (1-1), the second prismatic clamping rod (1-29) is connected with the first carriage (1-18) in a sliding way, the second prismatic clamping rod (1-29) is connected with the second lower-end clamping groove (1-22) in a matching way, the second prismatic clamping rod pushing spring (1-30) is arranged between the second prismatic clamping rod (1-29) and the first carriage (1-18), the first prismatic clamping rod (1-27) is connected with the second carriage (1-19) in a sliding way, the first prismatic clamping rod pushing spring (1-28) is arranged between the first prismatic clamping rod (1-27) and the second carriage (1-19, the prismatic clamping rod I (1-27) is connected with the lower end clamping groove II (1-22) in a matching mode, the inner end spherical clamping groove (1-23) is arranged at the inner end of the middle end cross groove (1-21), the spherical clamping rod (1-25) is connected with the middle end rectangular slider (1-24) in a sliding mode, the spherical clamping rod push spring (1-26) is arranged between the spherical clamping rod (1-25) and the middle end rectangular slider (1-24), and the spherical clamping rod (1-25) is connected with the inner end spherical clamping groove (1-23) in a matching mode.

3. The waste heat utilization environmental protection device according to claim 1, characterized in that: the crushing component (2) comprises an outer end sleeve (2-1), an upper end cover (2-2), a feeding port (2-3), a pressing rod (2-4), a pressing rod clamping groove (2-5), an inner end spherical clamping rod II (2-6), an inner end spherical clamping rod pushing spring II (2-7), a sliding rod I (2-8), a middle end pushing spring (2-9), a middle end driving frame (2-10), a rolling roller (2-11), a middle end rolling disc (2-12), a discharge hole I (2-13), a discharge hole II (2-14), a rotating sleeve I (2-15), a lower end rotating rod (2-16), a conical tooth I (2-17), a conical tooth II (2-18), a conical tooth III (2-19), a conical tooth IV (2-20), a conical tooth V (2-21), A bevel gear shaft I (2-22) and a discharge rod (2-23), wherein an upper end cover (2-2) is fixedly connected with an outer end sleeve (2-1), a feeding port (2-3) is arranged on the upper end cover (2-2), a pressing rod (2-4) is connected with the upper end cover (2-2) in a sliding manner, a pressing rod clamping groove (2-5) is arranged on the pressing rod (2-4), an inner end spherical clamping rod II (2-6) is connected with the upper end cover (2-2) in a sliding manner, an inner end spherical clamping rod push spring II (2-7) is arranged between the inner end spherical clamping rod II (2-6) and the upper end cover (2-2), the inner end spherical clamping rod II (2-6) is connected with the pressing rod clamping groove (2-5) in a matching manner, a sliding rod I (2-8) is connected with the pressing rod (2-4) in a sliding manner, the middle end push spring (2-9) is connected with the sliding rod I (2-8) in a sleeved mode, the sliding rod I (2-8) is fixedly connected with the middle end driving frame (2-10), the middle end push spring (2-9) is arranged between the push rod (2-4) and the middle end driving frame (2-10), the rolling roller (2-11) is rotatably connected with the middle end driving frame (2-10), the middle end rolling disc (2-12) is fixedly connected with the rotating sleeve I (2-15), the rotating sleeve I (2-15) is rotatably connected with the outer end sleeve (2-1), the lower end rotating rod (2-16) is connected with the middle end driving frame (2-10) in a sliding fit mode, the discharge hole I (2-13) is arranged on the middle end rolling disc (2-12), the discharge hole II (2-14) is arranged on the outer end sleeve (2-1), the discharging rod (2-23) is fixedly connected with the outer end sleeve (2-1), the bevel gear I (2-17) is fixedly connected with the lower end rotating rod (2-16), the bevel gear II (2-18) is fixedly connected with the rotating sleeve I (2-15), the lower end rotating rod (2-16) is rotatably connected with the rotating sleeve I (2-15), the bevel gear IV (2-20) is rotatably connected with the bevel gear III (2-19), the bevel gear IV (2-20) is in meshing transmission with the bevel gear I (2-17) and the bevel gear II (2-18), the bevel gear V (2-21) is in meshing transmission with the bevel gear III (2-19), the bevel gear shaft I (2-22) is fixedly connected with the bevel gear V (2-21), and the clutch rod II (1-17) is fixedly connected with the bevel gear shaft I (2-22).

4. The waste heat utilization environmental protection device according to claim 1, characterized in that: the chassis assembly (3) comprises a chassis body (3-1), a first support rod (3-2) and a fixed boss (3-3), the first support rod (3-2) and the fixed boss (3-3) are fixedly connected with the chassis body (3-1), a third bevel gear (2-19) is rotatably connected with the first support rod (3-2), a power bottom plate (1-1) is fixedly connected with the fixed boss (3-3), and an outer end sleeve (2-1) is fixedly connected with the chassis body (3-1).

5. The waste heat utilization environmental protection device according to claim 1, characterized in that: the input motor (1-3) is an external waste heat power generation module.

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