CN110777721A - Engineering deicing equipment - Google Patents

Abstract

The invention relates to engineering machinery, in particular to engineering deicing equipment. Ice can be shaved through the ice shoveling assembly; the ice shaving effect can be adjusted according to the actual situation; the collection of the crushed ice can be realized by the transportation assembly and the carrying assembly; can realize the same emission to the trash ice of collecting through the power supply, make things convenient for subsequent collection. Including the ice shoveling assembly, the transportation assembly, the delivery assembly, the power supply, connect belt one, spliced pole one, connect belt two, connect belt three, connect the bottom plate, a slide rail, transmission awl tooth two breaks away from with transmission awl tooth one and transmission awl tooth three, make transmission awl tooth one and seven meshing of transmission awl tooth simultaneously, make transmission awl tooth five and transmission awl tooth four meshing simultaneously, rotation through transmission awl tooth one, driving transmission awl tooth four and driving two antiport of clutch lever, driving articulated bull stick antiport through the clutch lever simultaneously, and then driving through the drive post and taking in the frame and upwards reversing, and resume original position.

Description

Engineering deicing equipment

Technical Field

The invention relates to engineering machinery, in particular to engineering deicing equipment.

Background

The deicing equipment is a common engineering machine, but the function of the common engineering deicing equipment is single.

Disclosure of Invention

The invention aims to provide engineering deicing equipment, which can realize the planing of ice through an ice shoveling assembly; the ice shaving effect can be adjusted according to the actual situation; the collection of the crushed ice can be realized by the transportation assembly and the carrying assembly; can realize the same emission to the trash ice of collecting through the power supply, make things convenient for subsequent collection.

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

the utility model provides an engineering deicing is equipped, includes shovel ice assembly, transportation assembly, delivery assembly, power supply, connects belt one, spliced pole one, connects belt two, connects belt three, connects bottom plate, slide rail, its characterized in that: the ice shoveling assembly is connected with the transportation assembly, the transportation assembly is connected with the delivery assembly, the delivery assembly is connected with the power source, the power source is connected with the first connecting belt, the first connecting column, the second connecting belt, the third connecting belt and the connecting bottom plate, and the slide rail is connected with the ice shoveling assembly, the transportation assembly, the delivery assembly and the power source.

As a further optimization of the technical scheme, the invention provides engineering deicing equipment, wherein an ice shoveling assembly comprises an N-shaped frame, a rectangular through hole, a hinged lug plate, a crankshaft connecting rod, a door-shaped frame, an ice shoveling rod, an I-shaped rod, an inner end rectangular slider, an inner end clamp, an inner end pushing spring, a side wall clamping groove, an ice shoveling boss and an ice shoveling pushing spring, the rectangular through hole is formed in the N-shaped frame, the hinged lug plate is fixedly connected with the N-shaped frame, the crankshaft is rotatably connected with the hinged lug plate, the crankshaft is hinged with the crankshaft connecting rod, the crankshaft connecting rod is hinged with the ice shoveling rod, the door-shaped frame is slidably connected with the N-shaped frame, the I-shaped rod is slidably connected with the ice shoveling rod, the inner end rectangular slider is rotatably connected with the I-shaped rod, the inner end clamp is slidably connected with the inner end rectangular slider, the inner end pushing spring is arranged between the two inner end clamps, the, the ice shoveling boss is connected with the ice shoveling rod in a sliding mode, the ice shoveling pushing spring is arranged between the ice shoveling boss and the ice shoveling rod, and the ice shoveling pushing spring is fixedly connected between the ice shoveling boss and the ice shoveling rod.

As a further optimization of the technical scheme, the engineering deicing equipment comprises a transportation assembly, wherein the transportation assembly comprises a side wall fixing frame, a first circular sliding groove, a second circular sliding groove, a third circular sliding groove, a cross rod, a transportation groove, an inner end sliding rod, a first sliding column, a second sliding column, a third sliding column, an inner end cross rod, a first bottom sliding column, an expansion cross rod, a first expansion push spring and a second expansion push spring, the first circular sliding groove, the second circular sliding groove and the third circular sliding groove are all arranged on the side wall fixing frame, the first circular sliding groove, the second circular sliding groove and the third circular sliding groove are concentrically arranged on the cross rod and are rotatably connected with the side wall fixing frame, the transportation groove is fixedly connected with the inner end sliding rod, the first sliding column, the second sliding column and the third sliding column are respectively slidably connected in the first circular sliding groove, the second, the first end sliding column is fixedly connected with the conveying groove, the second extension pushing spring is arranged and fixedly connected between the first end sliding column and the conveying groove, the first extension pushing spring is arranged at the inner end of the inner end cross rod and is slidably connected with the inner end cross rod, the first extension pushing spring is arranged and fixedly connected between the two extension cross rods, the extension cross rods are slidably connected with the conveying groove, the side wall fixing frame is fixedly connected with the N-shaped frame, and the third connecting belt is connected between the cross rod and the crankshaft.

As a further optimization of the technical scheme, the invention relates to engineering deicing equipment, wherein a carrying assembly comprises a carrying bottom plate, a carrying belt, a carrying roller I, a carrying roller II, a scraper, a carrying groove, a hinged sleeve, a hinged slide rod, an inner tension spring, a roller shaft I, a roller shaft II, an inner rectangular slider, an inner sliding column push spring, an underframe ear plate, an underframe hinged rod and a rectangular outer frame, wherein the underframe ear plate, the underframe hinged rod and the rectangular outer frame are fixedly connected with the carrying bottom plate, the roller shaft I is fixedly connected with the carrying roller II, the roller shaft I is rotatably connected with the underframe ear plate, the hinged slide rod is hinged with the roller shaft I, the hinged sleeve is slidably connected with the hinged slide rod, the inner sliding column push spring is arranged and fixedly connected between the hinged sleeve and the hinged slide rod, the hinged sleeve is hinged with the scraper, the scraper is hinged with the underframe hinged rod, the inner end sliding column is fixedly connected with the rectangular outer frame, the inner end rectangular slider is slidably connected with the inner end sliding column, an inner end sliding column push spring is connected with the inner end sliding column in a sleeved mode, the carrying bottom plate is fixedly connected with the side wall fixing frame, the carrying roller I is fixedly connected with the roller shaft II, the roller shaft II is rotatably connected with the inner end rectangular slider, the carrying belt is connected with the carrying roller I and the carrying roller II, the carrying groove is formed in the carrying belt, the connecting column I is fixedly connected with the roller shaft I, and the connecting belt II is arranged between the connecting column I and the cross rod.

As a further optimization of the technical scheme, the engineering deicing equipment comprises a power source, a containing outer frame, a feedback push plate, a motor support rod I, a motor support rod II, a motor support rod III, an input motor, input straight teeth, transmission bevel teeth I, transmission bevel teeth II, a hinged sleeve, a hinged push spring, a hinged driving rod, a transverse pull rod, transmission bevel teeth III, transmission bevel teeth IV, a left side sliding frame, a rear side sleeve, a hinged rotating rod, a driving column, a pull rod I, a fixed pull rod, a clutch push spring, a clutch rod I, a clutch rod II, a push plate push spring, a lower end slide rod, a transmission bevel teeth V, a transmission bevel teeth shaft I, a transmission bevel teeth VI, a transmission bevel teeth VII, a transmission bevel teeth rod, a transmission bevel teeth push spring and an inner end bevel teeth shaft, wherein the containing outer frame is in sliding connection with the feedback push plate, the push spring is arranged and fixedly connected between the containing outer frame and the feedback push plate, a first motor support rod, a second motor support rod and a third motor support rod are all fixedly connected with a motor support, an input motor is fixedly connected with the motor support, an input straight tooth is fixedly connected with the input motor, a transmission straight tooth is meshed with the input straight tooth and is fixedly connected with a transmission bevel tooth, the transmission bevel tooth is rotationally connected with a first motor support rod, a transmission bevel tooth is fixedly connected with a transmission bevel tooth, a transmission bevel tooth is rotationally connected with a second motor support rod, a clutch rod is fixedly connected with the transmission bevel tooth, the clutch rod is connected with a clutch rod in a matching way, a clutch push spring is connected with the clutch rod in a sleeving way, the clutch rod is slidably connected with a rear sleeve, the clutch push spring is arranged between the clutch rod and the rear sleeve, the rear sleeve is rotationally connected with the rear sleeve, the rear sleeve is fixedly connected with a hinge rotating rod, the hinged rotating rod is matched and connected with the driving column, the driving column is fixedly connected with the containing outer frame, the pull rod I is fixedly connected with the feedback push plate, the pull rod I is fixedly connected with the fixed pull rod, the fixed pull rod is hinged with the hinged driving rod in a sliding manner, the hinged driving rod is fixedly connected with the hinged sleeve, the hinged sleeve is matched and connected with the transverse pull rod, the hinged sleeve is fixedly connected with the inner end bevel gear shaft, the inner end bevel gear shaft is rotatably connected with the transmission bevel gear II, the hinged push spring is arranged between the transmission bevel gear II and the hinged driving rod, the hinged driving rod is rotatably connected with the hinged sleeve, the lower end slide rod is fixedly connected with the transverse pull rod, the lower end slide rod is fixedly connected with the motor bracket, the lower end push spring is sleeved and connected with the lower end slide rod, the lower end push spring is in an original state, the left side sliding frame is fixedly connected with the transmission bevel gear push spring, the transmission bevel gear, the transmission bevel gear pushing spring is connected with the transmission bevel gear rod in a sleeved mode, a transmission bevel gear shaft I is fixedly connected between a transmission bevel gear five and a transmission bevel gear six, the transmission bevel gear shaft I is rotatably connected with the left side sliding frame, a transmission bevel gear seven is rotatably connected with the left side sliding frame and meshed with the transmission bevel gear six, the motor support is fixedly connected with the connection bottom plate, the connection bottom plate is fixedly connected with the carrying bottom plate, the containing outer frame is hinged to the rectangular outer frame, and the connection belt is connected between the connection column I and the input motor.

As a further optimization of the technical scheme, the engineering deicing equipment provided by the invention is characterized in that one end of the N-shaped frame is provided with the traveling device.

The engineering deicing equipment has the beneficial effects that:

the invention relates to engineering deicing equipment, wherein a second transmission bevel gear is separated from a first transmission bevel gear and a third transmission bevel gear, the first transmission bevel gear is meshed with a seventh transmission bevel gear, a fifth transmission bevel gear is meshed with a fourth transmission bevel gear, the fourth transmission bevel gear is driven to drive a second clutch rod to rotate reversely through the rotation of the first transmission bevel gear, the hinged rotary rod is driven to rotate reversely through the clutch rod, a containing outer frame is driven to rotate upwards through a driving column, the original position is recovered, a feedback push plate and a transverse pull rod are recovered to the original position, the elastic action of a lower end push spring is released, the lower end push spring is recovered to the original position, the transverse pull rod is driven to recover to the original position, automatic unloading of ice blocks and recovery of the containing outer frame are realized, and the lower side use is facilitated.

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 third schematic view of the overall structure of the present invention;

FIG. 4 is a first schematic structural view of the ice-shoveling assembly of the present invention;

FIG. 5 is a schematic view of a second embodiment of the ice-shoveling assembly of the present invention;

FIG. 6 is a third schematic structural view of the ice-shoveling assembly of the present invention;

FIG. 7 is a first schematic view of a transport assembly according to the present invention;

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

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

FIG. 10 is a fourth schematic structural view of a transport assembly of the present invention;

FIG. 11 is a first schematic view of a carrier assembly according to the present invention;

FIG. 12 is a second schematic view of the carrying assembly of the present invention;

FIG. 13 is a first schematic view of the power source configuration of the present invention;

FIG. 14 is a schematic illustration of a second power source configuration of the present invention;

FIG. 15 is a third schematic structural view of the power source of the present invention;

FIG. 16 is a fourth schematic illustration of the power source configuration of the present invention;

FIG. 17 is a fifth schematic illustration of the power source configuration of the present invention;

fig. 18 is a sixth schematic view of the power source configuration of the present invention.

In the figure: an ice shoveling assembly 1; an N-shaped frame 1-1; a rectangular through hole 1-2; hinging the ear plates 1-3; 1-4 of a crankshaft; 1-5 crankshaft connecting rods; 1-6 of a portal frame; 1-7 parts of ice shoveling rod; 1-8 of a profile bar; 1-9 of rectangular sliders at the inner ends; inner end clips 1-10; inner end push spring 1-11; 1-12 side wall slots; ice shoveling bosses 1-13; 1-14 of ice shoveling and pushing spring; a transport assembly 2; a side wall fixing frame 2-1; 2-2 parts of a circular chute; 2-3 of a circular chute II; 2-4 of a circular chute; 2-5 of a cross rod; 2-6 of a conveying trough; 2-7 sliding rods at the inner ends; 2-8 of a sliding column I; 2-9 parts of a sliding column II; 2-10 parts of a sliding column III; 2-11 parts of inner end cross bars; 2-12 of a bottom sliding column I; 2-13 of an expansion cross bar; expanding push spring one 2-14; 2-15 parts of an expansion push spring; the carrying assembly 3; a carrying floor 3-1; a carrier belt 3-2; 3-3 parts of a carrying roller; a second carrying roller 3-4; 3-5 of a scraper plate; 3-6 parts of a carrying groove; hinge sleeves 3-7; hinged sliding rods 3-8; an inner end tension spring 3-9; 3-10 of a roller shaft I; 3-11 parts of a second roller shaft; 3-12 of rectangular sliders at the inner ends; inner end sliding columns 3-13; inner end sliding column push springs 3-14; 3-15 parts of chassis ear plates; undercarriage hinge bars 3-16; 3-17 of a rectangular outer frame; a power source 4; an outer containing frame 4-1; a feedback push plate 4-2; 4-3 of a motor bracket; 4-4 of a motor support rod I; 4-5 of a second motor support rod; 4-6 parts of a motor support rod; inputting a motor 4-7; inputting straight teeth 4-8; 4-9 parts of transmission straight teeth; 4-10 parts of a first transmission bevel gear; 4-11 parts of a second transmission bevel gear; 4-12 of an articulation sheath; hinged push springs 4-13; articulation drive links 4-14; 4-15 of transverse pull rods; 4-16 parts of transmission bevel gear III; 4-17 parts of transmission bevel gear; left side carriages 4-18; 4-19 parts of rear side sleeve; 4-20 of hinged rotating rod; drive columns 4-21; 4-22 parts of a first pull rod; 4-23 of a fixed pull rod; 4-24 of clutch push spring; 4-25 parts of a clutch lever I; a second clutch lever 4-26; 4-27 parts of push plate push spring; 4-28 of lower end push spring; a lower end sliding rod 4-29; 4-30 parts of transmission bevel gear; 4-31 of a transmission bevel gear shaft; sixty (4-32) transmission bevel teeth; 4-33 parts of transmission bevel gear seven; 4-34 of the transmission bevel gear rod; 4-35 parts of transmission bevel gear push spring; 4-36 of inner end bevel gear shaft; a first connecting belt 5; a first connecting column 6; a second connecting belt 7; a third connecting belt 8; a connecting bottom plate 9; a slide rail 10.

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 welding; fixing by means of thread fixing and the like, and using different fixing modes by combining 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 is formed by a hinge; the pin shaft, the short shaft and other connecting parts are movably connected; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 18, and an engineering deicing device includes an ice shoveling assembly 1, a transportation assembly 2, a carrying assembly 3, a power source 4, a first connecting belt 5, a first connecting column 6, a second connecting belt 7, a third connecting belt 8, a connecting bottom plate 9, and a slide rail 10, and is characterized in that: shovel ice assembly 1 is connected with transportation assembly 2, and transportation assembly 2 is connected with delivery assembly 3, and delivery assembly 3 is connected with power supply 4, and power supply 4 is connected with connecting belt 5, spliced pole 6, connecting belt two 7, connecting belt three 8, connecting bottom plate 9, and slide rail 10 is connected with shovel ice assembly 1, transportation assembly 2, delivery assembly 3, power supply 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 18, and the embodiment further describes the first embodiment, where the ice shoveling assembly 1 includes an N-shaped frame 1-1, a rectangular through hole 1-2, a hinged ear plate 1-3, a crankshaft 1-4, a crankshaft connecting rod 1-5, a door-shaped frame 1-6, an ice shoveling rod 1-7, an i-shaped rod 1-8, an inner end rectangular slider 1-9, an inner end clip 1-10, an inner end push spring 1-11, a side wall slot 1-12, an ice shoveling boss 1-13, and an ice shoveling push spring 1-14, the rectangular through hole 1-2 is disposed on the N-shaped frame 1-1, the hinged ear plate 1-3 is fixedly connected with the N-shaped frame 1-1, the crankshaft 1-4 is rotatably connected with the hinged ear plate 1-3, the crankshaft 1-4 is hinged with the crankshaft connecting rod 1-5, the ice shoveling device comprises a crankshaft connecting rod 1-5, an ice shoveling rod 1-7, a door-shaped frame 1-6, an N-shaped frame 1-1, an I-shaped rod 1-8, an inner end rectangular slider 1-9, inner end clips 1-10, inner end rectangular sliders 1-9, inner end push springs 1-11, side wall clamping grooves 1-12, inner end clips 1-10, side wall clamping grooves 1-12, ice shoveling bosses 1-13, ice shoveling push springs 1-14, ice shoveling push springs 1-13 and ice shoveling rods 1-7 and ice shoveling push springs 1-14, wherein the crankshaft connecting rod 1-5 is hinged with the ice shoveling rods 1-7, the door-shaped frame 1-6 is connected with the N-shaped frame 1-1 in a sliding mode, the inner end clips 1-10 are connected with the inner end rectangular sliders 1-9 in a sliding mode, the inner end push springs 1-11 are arranged between the two inner end.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1-18, and the transportation assembly 2 includes a sidewall holder 2-1, a first circular chute 2-2, a second circular chute 2-3, a third circular chute 2-4, a cross bar 2-5, a transportation slot 2-6, an inner sliding bar 2-7, a first sliding post 2-8, a second sliding post 2-9, a third sliding post 2-10, an inner cross bar 2-11, a first bottom sliding post 2-12, an expansion cross bar 2-13, an expansion push spring 2-14, an expansion push spring 2-15, wherein the first circular chute 2-2, the second circular chute 2-3, and the third circular chute 2-4 are all disposed on the sidewall holder 2-1, and the first circular chute 2-2, The circular sliding chute II 2-3 and the circular sliding chute III 2-4 are concentrically arranged on a cross rod 2-5 and are rotationally connected with a side wall fixing frame 2-1, the transportation groove 2-6 is fixedly connected with an inner end sliding rod 2-7, the sliding column I2-8, the sliding column II 2-9 and the sliding column III 2-10 are fixedly connected with the inner end sliding rod 2-7, the sliding column I2-8, the sliding column II 2-9 and the sliding column III 2-10 are respectively and slidably connected in the circular sliding chute I2-2, the circular sliding chute II 2-3 and the circular sliding chute III 2-4, the inner end cross rod 2-11 is slidably connected with a bottom end sliding column I2-12, the end sliding column I2-12 is fixedly connected with the transportation groove 2-6, the expansion push spring II 2-15 is arranged and fixedly connected between the end sliding column I2-12 and the transportation groove 2-6, the expansion push springs I2-14 are arranged at the inner ends of the inner end cross rods 2-11, the expansion cross rods 2-13 are connected with the inner end cross rods 2-11 in a sliding mode, the expansion push springs I2-14 are arranged and fixedly connected between the two expansion cross rods 2-13, the expansion cross rods 2-13 are connected with the conveying grooves 2-6 in a sliding mode, the side wall fixing frames 2-1 are fixedly connected with the N-shaped frames 1-1, and the connecting belts III 8 are connected between the cross rods 2-5 and the crankshafts 1-4.

The fourth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-18, the carrying assembly 3 includes a carrying bottom plate 3-1, a carrying belt 3-2, a carrying roller 3-3, a carrying roller two 3-4, a scraping plate 3-5, a carrying groove 3-6, a hinge sleeve 3-7, a hinge slide bar 3-8, an inner end tension spring 3-9, a roller shaft one 3-10, a roller shaft two 3-11, an inner end rectangular slider 3-12, an inner end sliding column 3-13, an inner end sliding column push spring 3-14, an underframe ear plate 3-15, an underframe hinge rod 3-16, a rectangular outer frame 3-17, an underframe ear plate 3-15, an underframe hinge rod 3-16, and a rectangular outer frame 3-17, all fixedly connected to the carrying bottom plate 3-1, the roller shaft I3-10 is fixedly connected with the carrying roller II 3-4, the roller shaft I3-10 is rotatably connected with the bottom frame ear plate 3-15, the hinged slide bar 3-8 is hinged with the roller shaft I3-10, the hinged sleeve 3-7 is slidably connected with the hinged slide bar 3-8, the inner end sliding column push spring 3-14 is arranged and fixedly connected between the hinged sleeve 3-7 and the hinged slide bar 3-8, the hinged sleeve 3-7 is hinged with the scraping plate 3-5, the scraping plate 3-5 is hinged with the bottom frame hinged bar 3-16, the inner end sliding column 3-13 is fixedly connected with the rectangular outer frame 3-17, the inner end rectangular slider 3-12 is slidably connected with the inner end sliding column 3-13, the inner end sliding column push spring 3-14 is sleeved with the inner end sliding column 3-13, the carrying bottom plate 3-1 is fixedly connected with the side wall fixing frame 2-1, the carrying roller I3-3 is fixedly connected with the roller shaft II 3-11, the roller shaft II 3-11 is rotatably connected with the inner end rectangular slider 3-12, the carrying belt 3-2 is connected with the carrying roller I3-3 and the carrying roller II 3-4, the carrying groove 3-6 is arranged on the carrying belt 3-2, the connecting column I6 is fixedly connected with the roller shaft I3-10, and the connecting belt II 7 is arranged between the connecting column I6 and the cross rod 2-5.

The fifth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-18, and the power source 4 includes an outer storage frame 4-1, a feedback push plate 4-2, a motor support 4-3, a motor support rod one 4-4, a motor support rod two 4-5, a motor support rod three 4-6, an input motor 4-7, an input straight tooth 4-8, a transmission straight tooth 4-9, a transmission bevel tooth one 4-10, a transmission bevel tooth two 4-11, a hinge sleeve 4-12, a hinge push spring 4-13, a hinge drive rod 4-14, a transverse pull rod 4-15, a transmission bevel tooth three 4-16, a transmission bevel tooth four 4-17, a left side carriage 4-18, a rear side sleeve 4-19, a hinge rotary rod 4-20, a drive column 4-21, a, 4-22 parts of a first pull rod, 4-23 parts of a fixed pull rod, 4-24 parts of a clutch push spring, 4-25 parts of a first clutch rod, 4-26 parts of a second clutch rod, 4-27 parts of a push plate push spring, 4-28 parts of a lower end push spring, 4-29 parts of a lower end slide rod, 4-30 parts of a transmission bevel gear, 4-31 parts of a transmission bevel gear shaft, 4-32 parts of a transmission bevel gear, seven 4-33 parts of a transmission bevel gear, 4-34 parts of a transmission bevel gear push spring, 4-35 parts of a transmission bevel gear push spring and 4-36 parts of an inner end bevel gear shaft, wherein a containing outer frame 4-1 is in sliding connection with a feedback push plate 4-2, the push plate push spring 4-27 is arranged and fixedly connected between the containing outer frame 4-1 and the feedback push plate 4-2, and the first motor support rod, 4-5 parts of a second motor support rod and the, an input motor 4-7 is fixedly connected with a motor bracket 4-3, an input straight tooth 4-8 is fixedly connected with the input motor 4-7, a transmission straight tooth 4-9 is meshed with the input straight tooth 4-8, a transmission straight tooth 4-9 is fixedly connected with a transmission bevel gear I4-10, the transmission bevel gear I4-10 is rotatably connected with a motor bracket rod I4-4, a transmission bevel gear III 4-16 is fixedly connected with a transmission bevel gear IV 4-17, the transmission bevel gear IV 4-17 is rotatably connected with a motor bracket rod II 4-5, a clutch rod II 4-26 is fixedly connected with the transmission bevel gear IV 4-17, the clutch rod II 4-26 is in fit connection with the clutch rod I4-25, a clutch push spring 4-24 is in socket connection with the clutch rod I4-25, the clutch rod I4-25 is in sliding connection with a rear side sleeve 4-19, the clutch push spring 4-24 is arranged between the clutch rod I4-25 and the rear side sleeve 4-19, the clutch push spring 4-24 is connected with the rear side sleeve 4-19 in a sleeved mode, the rear side sleeve 4-19 is connected with the motor support rod III 4-6 in a rotating mode, the rear side sleeve 4-19 is fixedly connected with the hinged rotating rod 4-20, the hinged rotating rod 4-20 is connected with the driving column 4-21 in a matched mode, the driving column 4-21 is fixedly connected with the containing outer frame 4-1, the pull rod I4-22 is fixedly connected with the feedback push plate 4-2, the pull rod I4-22 is fixedly connected with the fixed pull rod 4-23, the fixed pull rod 4-23 is hinged with the hinged driving rod 4-14 in a sliding mode, the hinged driving rod 4-14 is fixedly connected with the hinged sleeve 4-12, the hinged sleeve 4-12 is connected with the transverse pull rod 4-15 in a matched mode, the hinged sleeve 4-12 is fixedly connected with an inner end bevel gear shaft 4-36, the inner end bevel gear shaft 4-36 is rotatably connected with a transmission bevel gear II 4-11, a hinged push spring 4-13 is arranged between the transmission bevel gear II 4-11 and a hinged driving rod 4-14, the hinged driving rod is rotatably connected with the hinged sleeve 4-12, a lower end sliding rod 4-29 is fixedly connected with a transverse pull rod 4-15, a lower end sliding rod 4-29 is fixedly connected with a motor bracket 4-3, a lower end push spring 4-28 is connected with a lower end sliding rod 4-29 in a sleeved mode, the lower end push spring 4-28 is in an original state, a left side sliding frame 4-18 is fixedly connected with a transmission bevel gear rod 4-34, a transmission bevel gear push spring 4-35 is fixedly connected and arranged between the transmission bevel gear rod 4-34 and the transverse pull rod 4-15, the transmission bevel gear rod 4-34 is connected with the transverse pull rod 4-15 in a sliding mode, the transmission bevel gear push spring 4-35 is sleeved with the transmission bevel gear rod 4-34, the transmission bevel gear shaft I4-31 is fixedly connected between the transmission bevel gear V4-30 and the transmission bevel gear VI 4-32, the transmission bevel gear shaft I4-31 is rotatably connected with the left side sliding frame 4-18, the transmission bevel gear VII 4-33 is meshed with the transmission bevel gear VI 4-32, the motor support 4-3 is fixedly connected with the connecting bottom plate 9, the connecting bottom plate 9 is fixedly connected with the carrying bottom plate 3-1, the containing outer frame 4-1 is hinged with the rectangular outer frame 3-17, and the connecting belt I5 is connected between the connecting column I6 and the input motor 4-7.

The sixth specific implementation mode:

the present embodiment will be described with reference to fig. 1 to 18, and the present embodiment further describes the first embodiment, in which a traveling device is provided at one end of the N-shaped frame 1-1.

The invention relates to engineering deicing equipment, which has the working principle that: when the ice crusher is used, the input motor 4-7 is started, the connecting belt I5 is driven to move, the connecting belt II 7 is driven to rotate through the connecting column I6, the cross rod 2-5 is driven to rotate, the crankshaft 1-4 is driven to rotate through the connecting belt III 8, the ice shoveling rod 1-7 is driven to move through the crankshaft connecting rod 1-5 by the crankshaft 1-4, the ice shoveling rod 1-7 moves, the ice shoveling boss 1-13 is in contact with the ice surface to complete the crushing process of the ice surface, the ice shoveling boss 1-13 is driven to swing around the inner end rectangular slider 1-9 by the ice shoveling rod 1-7, when the ice shoveling boss 1-13 is in contact with the ice surface to complete the crushing process of the ice surface, the ice shoveling boss 1-13 swings to the rear side through the driving of the ice shoveling rod 1-7, and pushing the crushed ice blocks to move backwards; the ice breaking device can adjust the ice breaking effect according to actual conditions, manually slide the rectangular slider 1-9 along the door-shaped frame 1-6, meanwhile, the rectangular slider 1-9 is connected with the side wall clamping groove 1-12 through the matching of the inner end clamp 1-10 and the side wall clamping groove 1-12, the fixing of the using position of the rectangular slider 1-9 in the door-shaped frame 1-6 is completed through the inner end clamp 1-10 and the side wall clamping groove 1-12 while the rectangular slider 1-9 slides along the door-shaped frame 1-6 under the driving of the inner end push spring 1-11, when the using position of the rectangular slider 1-9 in the door-shaped frame 1-6 is changed, the position of the moving axis of the ice shoveling rod 1-7 is changed, further, the moving amplitude of the ice shoveling rod 1-7 is changed, further, the contact time and the contact depth of the ice shoveling boss 1-13 and the ice surface are influenced through the moving amplitude of the ice shoveling rod 1-, thereby realizing the adjustment of the ice crushing effect; when the cross rod 2-5 rotates, the first sliding column 2-8, the second sliding column 2-9 and the third sliding column 2-10 are matched and connected with the first circular sliding groove 2-2, the second circular sliding groove 2-3 and the third circular sliding groove 2-4, so that the transport groove 2-6 keeps a position vertical to a rotating shaft line of the cross rod 2-5 while rotating along with the cross rod 2-5, and crushed ice blocks are placed through the movement of the transport groove 2-6; when the transport groove 2-6 filled with the broken ice blocks rotates to pass through the highest point of the first circular chute 2-2, under the action of the gravity of the ice blocks, the ice blocks are separated from the transport groove 2-6 and fall into the carrying belt 3-2, when the cross rod 2-5 rotates, the connecting column one 6 is driven to rotate through the connecting belt two 7, the roller shaft one 3-10 is driven to rotate, the carrying belt 3-2 is driven to rotate through the carrying roller two 3-4, the ice blocks are transported to the left side through the carrying belt 3-2, and the friction force between the ice blocks and the carrying belt 3-2 can be increased by the carrying groove 3-6, so that the ice blocks are not easy to fall off; the ice blocks fall into the containing outer frame 4-1 and are accumulated on the feedback push plate 4-2 through the transportation of the carrier belt 3-2, the feedback push plate 4-2 moves downwards along the containing outer frame 4-1 along with the accumulation of the ice blocks, the pull rod I4-22 and the fixed pull rod 4-23 move downwards simultaneously, the hinge driving rod 4-14 is driven to move through the fixed pull rod 4-23 and drives the hinge sleeve 4-12 to move along the transverse pull rod 4-15, the transmission bevel gear II 4-11 is driven by the inner end bevel gear shaft 4-36 to contact with the transmission bevel gear I4-10 and the transmission bevel gear III 4-16 through the driving of the hinge sleeve 4-12, and the transmission bevel gear II 4-11 is driven between the transmission bevel gear I4-10 and the transmission bevel gear III 4-16, the driving bevel gear III 4-16 rotates to drive the clutch lever II 4-26 to move, the clutch lever I4-25 drives the hinged rotating rod 4-20 to rotate, the hinged rotating rod 4-20 drives the driving column 4-21 and drives the containing outer frame 4-1 to turn downwards along the rectangular outer frame 3-17, so that ice blocks in the containing outer frame 4-1 are separated from the containing outer frame 4-1 along with the turning of the containing outer frame 4-1 to finish the dumping of the ice blocks, when the containing outer frame 4-1 turns downwards along the rectangular outer frame 3-17 to a certain position, the containing outer frame 4-1 does not move, the hinged rotating rod 4-20 does not move, the clutch lever I4-25 and the clutch lever II 4-26 relatively rotate, and the clutch lever I4-25, The transmission of the second clutch lever 4-26 is failed; when the hinged sleeve 4-12 is contacted with the transverse pull rod 4-15, the transmission bevel gear II 4-11 is in transmission with the transmission bevel gear I4-10 and the transmission bevel gear III 4-16; when the ice cubes are poured, the transverse pull rod 4-15 is manually pushed to move towards the right side, the transverse pull rod 4-15 pushes the hinged sleeve 4-12 to drive the transmission bevel gear two 4-11 to be separated from the transmission bevel gear one 4-10 and the transmission bevel gear three 4-16 through the inner end bevel gear shaft 4-36, the transmission bevel gear one 4-10 is meshed with the transmission bevel gear seven 4-33, the transmission bevel gear five 4-30 is meshed with the transmission bevel gear four 4-17, the transmission bevel gear four 4-17 is driven to drive the clutch rod two 4-26 to rotate reversely through the rotation of the transmission bevel gear one 4-10, the hinged rotating rod 4-20 is driven to rotate reversely through the clutch rod one 4-25, and the containing outer frame 4-1 is driven to rotate upwards through the driving column 4-21, and the original position is restored, the feedback push plate 4-2 and the transverse pull rod 4-15 are restored to the original position, the elastic action of the lower end push spring 4-28 is released, the lower end push spring 4-28 is restored to the original position, the transverse pull rod 4-15 is driven to restore to the original position, the automatic unloading of ice blocks and the resetting of the containing outer frame 4-1 are further realized, and the lower side use is facilitated.

Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and variations can be made by those skilled in the art within the spirit and scope of the present invention; modifying; and the addition or the replacement also belongs to the protection scope of the invention.

Claims (6)

1. The utility model provides an engineering deicing is equipped, includes shovel ice assembly (1), transportation assembly (2), delivery assembly (3), power supply (4), connects belt (5), spliced pole (6), connects belt two (7), connects belt three (8), connects bottom plate (9), slide rail (10), its characterized in that: shovel ice assembly (1) is connected with transportation assembly (2), and transportation assembly (2) are connected with delivery assembly (3), and delivery assembly (3) are connected with power supply (4), and power supply (4) are connected with connection belt (5), spliced pole (6), connection belt two (7), connection belt three (8), connection bottom plate (9), and slide rail (10) are connected with shovel ice assembly (1), transportation assembly (2), delivery assembly (3), power supply (4).

2. An engineering deicing equipment according to claim 1, characterized in that: the ice shoveling assembly (1) comprises an N-shaped frame (1-1), rectangular through holes (1-2), hinged lug plates (1-3), a crankshaft (1-4), a crankshaft connecting rod (1-5), a door-shaped frame (1-6), ice shoveling rods (1-7), I-shaped rods (1-8), inner-end rectangular sliders (1-9), inner-end clamps (1-10), inner-end push springs (1-11), side-wall clamping grooves (1-12), ice shoveling bosses (1-13) and ice shoveling push springs (1-14), wherein the rectangular through holes (1-2) are arranged on the N-shaped frame (1-1), the hinged lug plates (1-3) are fixedly connected with the N-shaped frame (1-1), the crankshaft (1-4) is rotatably connected with the hinged lug plates (1-3), and the crankshaft (1-4) is hinged with the crankshaft connecting rod (1-5), the crankshaft connecting rod (1-5) is hinged with the ice shoveling rod (1-7), the door-shaped frame (1-6) is connected with the N-shaped frame (1-1) in a sliding manner, the I-shaped rod (1-8) is connected with the ice shoveling rod (1-7) in a sliding manner, the inner-end rectangular slider (1-9) is connected with the I-shaped rod (1-8) in a rotating manner, the inner-end clips (1-10) are connected with the inner-end rectangular slider (1-9) in a sliding manner, the inner-end push spring (1-11) is arranged between the two inner-end clips (1-10), the side-wall clamping groove (1-12) is arranged on the door-shaped frame (1-6), the inner-end clips (1-10) are connected with the side-wall clamping groove (1-12) in a matching manner, the ice shoveling boss (1-13) is connected with the ice shoveling rod (1-7) in a sliding manner, and the ice shoveling push spring (1-14) is arranged between the, the ice shoveling push spring (1-14) is fixedly connected between the ice shoveling boss (1-13) and the ice shoveling rod (1-7).

3. An engineering deicing equipment according to claim 1, characterized in that: the transportation assembly (2) comprises a side wall fixing frame (2-1), a first circular sliding groove (2-2), a second circular sliding groove (2-3), a third circular sliding groove (2-4), a cross rod (2-5), a transportation groove (2-6), a sliding rod at the inner end (2-7), a first sliding column (2-8), a second sliding column (2-9), a third sliding column (2-10), a cross rod at the inner end (2-11), a first sliding column at the bottom end (2-12), an expansion cross rod (2-13), a first expansion push spring (2-14), a second expansion push spring (2-15), wherein the first circular sliding groove (2-2), the second circular sliding groove (2-3) and the third circular sliding groove (2-4) are all arranged on the side wall fixing frame (2-1), and the first circular sliding groove (2-2) is, The circular sliding chute II (2-3) and the circular sliding chute III (2-4) are concentrically arranged on a cross rod (2-5) and rotatably connected with a side wall fixing frame (2-1), the transportation chute (2-6) is fixedly connected with an inner end sliding rod (2-7), the sliding column I (2-8), the sliding column II (2-9) and the sliding column III (2-10) are fixedly connected with the inner end sliding rod (2-7), the sliding column I (2-8), the sliding column II (2-9) and the sliding column III (2-10) are respectively and slidably connected in the circular sliding chute I (2-2), the circular sliding chute II (2-3) and the circular sliding chute III (2-4), an inner end cross rod (2-11) is slidably connected with a bottom end sliding column I (2-12), and an end sliding column I (2-12) is fixedly connected with the transportation chute (2-6), the expansion push spring II (2-15) is arranged and fixedly connected between the end sliding column I (2-12) and the conveying groove (2-6), the expansion push spring I (2-14) is arranged at the inner end of the inner end cross rod (2-11), the expansion cross rod (2-13) is in sliding connection with the inner end cross rod (2-11), the expansion push spring I (2-14) is arranged and fixedly connected between the two expansion cross rods (2-13), the expansion cross rod (2-13) is in sliding connection with the conveying groove (2-6), the side wall fixing frame (2-1) is fixedly connected with the N-shaped frame (1-1), and the connecting belt III (8) is connected between the cross rod (2-5) and the crankshaft (1-4).

4. An engineering deicing equipment according to claim 1, characterized in that: the carrying assembly (3) comprises a carrying bottom plate (3-1), a carrying belt (3-2), a carrying roller I (3-3), a carrying roller II (3-4), a scraper (3-5), a carrying groove (3-6), a hinged sleeve (3-7), a hinged slide rod (3-8), an inner end tension spring (3-9), a roller shaft I (3-10), a roller shaft II (3-11), an inner end rectangular slider (3-12), an inner end sliding column (3-13), an inner end sliding column push spring (3-14), an underframe ear plate (3-15), an underframe hinged rod (3-16), a rectangular outer frame (3-17), wherein the underframe ear plate (3-15), the underframe hinged rod (3-16) and the rectangular outer frame (3-17) are fixedly connected with the carrying bottom plate (3-1), the roller shaft I (3-10) is fixedly connected with the carrying roller II (3-4), the roller shaft I (3-10) is rotatably connected with the bottom frame lug plate (3-15), the hinged sliding rod (3-8) is hinged with the roller shaft I (3-10), the hinged sleeve (3-7) is slidably connected with the hinged sliding rod (3-8), the inner end sliding column push spring (3-14) is arranged and fixedly connected between the hinged sleeve (3-7) and the hinged sliding rod (3-8), the hinged sleeve (3-7) is hinged with the scraping plate (3-5), the scraping plate (3-5) is hinged with the bottom frame hinged rod (3-16), the inner end sliding column (3-13) is fixedly connected with the rectangular outer frame (3-17), the inner end rectangular sliding column (3-12) is slidably connected with the inner end sliding column (3-13), an inner end sliding column push spring (3-14) is connected with an inner end sliding column (3-13) in a sleeved mode, a carrying bottom plate (3-1) is fixedly connected with a side wall fixing frame (2-1), a carrying roller I (3-3) is fixedly connected with a roller shaft II (3-11), the roller shaft II (3-11) is rotatably connected with an inner end rectangular slider (3-12), a carrying belt (3-2) is connected with the carrying roller I (3-3) and the carrying roller II (3-4), a carrying groove (3-6) is arranged on the carrying belt (3-2), a connecting column I (6) is fixedly connected with the roller shaft I (3-10), and a connecting belt II (7) is arranged between the connecting column I (6) and a cross rod (2-5).

5. An engineering deicing equipment according to claim 1, characterized in that: the power source (4) comprises a storage outer frame (4-1), a feedback push plate (4-2), a motor support (4-3), a motor support rod I (4-4), a motor support rod II (4-5), a motor support rod III (4-6), an input motor (4-7), input straight teeth (4-8), transmission straight teeth (4-9), transmission bevel teeth I (4-10), transmission bevel teeth II (4-11), a hinged sleeve (4-12), a hinged push spring (4-13), a hinged driving rod (4-14), a transverse pull rod (4-15), transmission bevel teeth III (4-16), transmission bevel teeth IV (4-17), a left side sliding frame (4-18), a rear side sleeve (4-19), a hinged rotating rod (4-20), A driving column (4-21), a first pull rod (4-22), a fixed pull rod (4-23), a clutch push spring (4-24), a first clutch rod (4-25), a second clutch rod (4-26), a push plate push spring (4-27), a lower end push spring (4-28), a lower end slide rod (4-29), a fifth transmission bevel gear (4-30), a first transmission bevel gear shaft (4-31), a sixth transmission bevel gear (4-32), a seventh transmission bevel gear (4-33), a transmission bevel gear rod (4-34), a fifth transmission bevel gear push spring (4-35) and an inner end bevel gear shaft (4-36), wherein a containing outer frame (4-1) is in sliding connection with a feedback push plate (4-2), the push plate push spring (4-27) is arranged and fixedly connected between the containing outer frame (4-1) and the feedback push plate (4-2), a first motor support rod (4-4), a second motor support rod (4-5) and a third motor support rod (4-6) are fixedly connected with a motor support (4-3), an input motor (4-7) is fixedly connected with the motor support (4-3), an input straight tooth (4-8) is fixedly connected with the input motor (4-7), a transmission straight tooth (4-9) is meshed with the input straight tooth (4-8), a transmission straight tooth (4-9) is fixedly connected with a first transmission bevel tooth (4-10), the first transmission bevel tooth (4-10) is rotatably connected with the first motor support rod (4-4), the third transmission bevel tooth (4-16) is fixedly connected with a fourth transmission bevel tooth (4-17), the fourth transmission bevel tooth (4-17) is rotatably connected with the second motor support rod (4-5), a clutch rod II (4-26) is fixedly connected with a transmission bevel gear IV (4-17), the clutch rod II (4-26) is in fit connection with a clutch rod I (4-25), a clutch push spring (4-24) is in socket connection with the clutch rod I (4-25), the clutch rod I (4-25) is in sliding connection with a rear side sleeve (4-19), the clutch push spring (4-24) is arranged between the clutch rod I (4-25) and the rear side sleeve (4-19), the clutch push spring (4-24) is in socket connection with the rear side sleeve (4-19), the rear side sleeve (4-19) is in rotational connection with a motor support rod III (4-6), the rear side sleeve (4-19) is fixedly connected with a hinge rotating rod (4-20), the hinge rotating rod (4-20) is in fit connection with a driving column (4-21), the driving column (4-21) is fixedly connected with the containing outer frame (4-1), the pull rod I (4-22) is fixedly connected with the feedback push plate (4-2), the pull rod I (4-22) is fixedly connected with the fixed pull rod (4-23), the fixed pull rod (4-23) is slidably hinged with the hinged driving rod (4-14), the hinged driving rod (4-14) is fixedly connected with the hinged sleeve (4-12), the hinged sleeve (4-12) is matched and connected with the transverse pull rod (4-15), the hinged sleeve (4-12) is fixedly connected with the inner end bevel gear shaft (4-36), the inner end bevel gear shaft (4-36) is rotatably connected with the transmission bevel gear II (4-11), and the hinged push spring (4-13) is arranged between the transmission bevel gear II (4-11) and the hinged driving rod (4-14), the hinged driving rod is rotatably connected with the hinged sleeve (4-12), the lower end sliding rod (4-29) is fixedly connected with the transverse pull rod (4-15), the lower end sliding rod (4-29) is fixedly connected with the motor bracket (4-3), the lower end push spring (4-28) is connected with the lower end sliding rod (4-29) in a sleeved mode, the lower end push spring (4-28) is in an original state, the left side sliding frame (4-18) is fixedly connected with the transmission bevel gear rod (4-34), the transmission bevel gear push spring (4-35) is fixedly connected and arranged between the transmission bevel gear rod (4-34) and the transverse pull rod (4-15), the transmission bevel gear rod (4-34) is connected with the transverse pull rod (4-15) in a sliding mode, the transmission bevel gear push spring (4-35) is connected with the transmission bevel gear rod (4-34) in a sleeved mode, the transmission bevel gear shaft I (4-31) is fixedly connected between the transmission bevel gear V (4-30) and the transmission bevel gear VI (4-32), the transmission bevel gear shaft I (4-31) is rotatably connected with the left side sliding frame (4-18), the transmission bevel gear seven (4-33) is meshed with the transmission bevel gear VI (4-32), the motor support (4-3) is fixedly connected with the connecting bottom plate (9), the connecting bottom plate (9) is fixedly connected with the carrying bottom plate (3-1), the containing outer frame (4-1) is hinged with the rectangular outer frame (3-17), and the connecting belt I (5) is connected between the connecting column I (6) and the input motor (4-7).

6. An engineering deicing equipment according to claim 2, characterized in that: one end of the N-shaped frame (1-1) is provided with a walking device.

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