CN111331489A - Intelligent steel bar rust removal equipment - Google Patents

Abstract

The invention relates to the field of intellectualization, in particular to intelligent steel bar rust removal equipment. The rust removal treatment on the outer side of the steel bar can be realized; the reciprocating cleaning of the reinforcing steel bars can be realized, so that the treatment efficiency is conveniently improved; the stroke of reciprocating work can be adjusted according to actual conditions, and then the rust cleaning is emphatically handled to convenient a certain section position to the reinforcing bar. Including the rust cleaning assembly, the chassis assembly, the transition assembly, the power supply, start input motor, and then transfer input awl tooth and rotate, and then driving awl tooth one through input awl tooth, the motion of awl tooth two, middle-end sliding sleeve initial position is connected with the cooperation of awl tooth boss two, and then the cooperation between boss cooperation groove on the middle-end sliding sleeve and the transfer line boss is connected and is driving transfer line one and rotating, and then driving friction pulley two and rotating, and then driving friction pulley one and rotating, and then driving the output lever and rotating, and then conveniently carry out power take off through the output lever.

Description

Intelligent steel bar rust removal equipment

Technical Field

The invention relates to the field of intellectualization, in particular to intelligent steel bar rust removal equipment.

Background

The intelligent steel bar rust removal equipment is a common equipment in the intelligent field, but the function of the common intelligent steel bar rust removal equipment is single.

Disclosure of Invention

The invention aims to provide intelligent steel bar rust removal equipment which can realize rust removal treatment on the outer side of a steel bar; the reciprocating cleaning of the reinforcing steel bars can be realized, so that the treatment efficiency is conveniently improved; the stroke of reciprocating work can be adjusted according to actual conditions, and then the rust cleaning is emphatically handled to convenient a certain section position to the reinforcing bar.

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

the utility model provides an intelligent reinforcing bar rust cleaning equipment, includes rust cleaning assembly, chassis assembly, transition assembly, power supply, the rust cleaning assembly is connected with the chassis assembly, and the transition assembly is connected with the chassis assembly, and the power supply is connected with the transition assembly.

As a further optimization of the technical scheme, the invention discloses an intelligent steel bar rust removal device, wherein a rust removal assembly comprises a rust removal outer frame, a bevel gear sheave, a rectangular groove, a roller, a belt wheel I, a belt wheel II, a buffer sleeve I, a buffer sleeve II, a buffer push spring I, a buffer push spring II, a support I, a belt wheel III, a middle end slider, a middle end sliding column, a middle end push spring, a roller, an iron brush, an inner end sliding column I, an inner end push spring I, a belt wheel IV, a bottom end bevel gear and a lower end boss, wherein the bevel gear sheave is rotatably connected with the rust removal outer frame, the rectangular groove is arranged on the bevel gear sheave, the roller is rotatably connected with the rust removal outer frame, the belt wheel I is rotatably connected with the rust removal outer frame, the belt wheel II is rotatably connected between the belt wheel I and the belt wheel II, the belt wheel III and the belt wheel IV, and the buffer sleeve I is hinged with the rust removal, the first buffer sleeve is connected with the second buffer sleeve in a sliding way, the first buffer push spring, the buffer push spring II is arranged at two ends of the buffer sleeve II, the buffer push spring II is connected with the buffer sleeve II in a sleeved mode, the buffer sleeve II is connected with the support I in a hinged mode, the support I is connected with the derusting outer frame in a rotating mode, the middle-end sliding column is fixedly connected with the support I, the middle-end sliding column is connected with the middle-end sliding column in a sliding mode, the middle-end push spring is connected with the middle-end sliding column in a sleeved mode, the belt wheel III is connected with the middle-end sliding column in a rotating mode, the roller is connected with the support I in a rotating mode, the belt wheel IV is fixedly connected with the roller, the inner-end sliding column I is fixedly connected with the roller, the inner-end push spring I is connected with the inner-end sliding column I in a sleeved mode, the iron brush is connected with the inner-end sliding column I in a sliding mode, the inner-end push.

According to the technical scheme, the intelligent steel bar rust removal equipment comprises a chassis body, upper connecting rods, a first sliding groove, a second sliding groove and connecting pins, wherein the first sliding groove and the second sliding groove are arranged on the chassis body, the number of the rust removal assemblies is two, the upper connecting rods are fixedly connected between two rust removal outer frames, the connecting pins are arranged in a plurality of positions, the connecting pins are fixedly connected with the chassis body, a boss at the lower end of the connecting pin is attached to the chassis body, a rectangular groove is connected with the connecting pins in a matched mode, and rollers are arranged in the first sliding groove.

As a further optimization of the technical scheme, the invention discloses intelligent steel bar rust removal equipment, wherein a transition combination body comprises a transition underframe, a first transmission belt wheel, a first connecting belt, a second transmission belt wheel, an N-shaped frame, a first driving slider, a second driving slider, a first inner clamping groove, a second inner clamping groove, a first inner clamp push spring, a second inner clamp push spring, a first arc-shaped sliding rod push spring, a matching roller, a first hinge rod, a first tension spring, a second arc-shaped sliding rod push spring, a second tension spring, a second hinge rod, a matching roller, a first pull rod, a second pull rod, a waist groove rod, a spherical inner end push spring A, a spherical inner clamping groove and a matching belt wheel, wherein the first transmission belt wheel and the second transmission belt wheel are rotatably connected with the transition underframe, the first transmission belt wheel is arranged between the first transmission belt wheel and the second, the first inner clamping groove and the second inner clamping groove are arranged at the inner end of the N-shaped frame, the first driving slide block, the second driving slide block and the N-shaped frame are connected in a sliding mode, the first inner end clamp is connected with the first driving slide block in a sliding mode, the first inner end clamp is arranged between the first inner end clamp and the first driving slide block, the first inner end clamp is connected with the first inner clamping groove in a matching mode, the second inner end clamp is connected with the second driving slide block in a sliding mode, the second inner end clamp is arranged between the second inner end clamp and the second driving slide block, the second inner end clamp is connected with the second inner clamping groove in a matching mode, the first arc-shaped slide rod is connected with the first driving slide block in a sliding mode, the first arc-shaped slide rod is connected with the first arc-shaped slide rod in a sleeving mode, the first hinge rod is connected with the first driving slide block in a rotating mode, the first matching roller is connected with, the second arc-shaped sliding rod push spring is connected with the second arc-shaped sliding rod in a sleeved mode, the second tension spring is connected between the second driving sliding block and the second hinge rod, the second hinge rod is connected with the second driving sliding block in a hinged mode, the second matching roller is connected with the second hinge rod in a rotating mode, the first hinge rod is connected with the first hinge rod in a hinged mode, the second pull rod is connected with the second hinge rod in a hinged mode, the waist groove rod is fixedly connected with the second pull rod, the inner end spherical rod is connected with the second pull rod in a sliding mode, the inner end push spring A is arranged and fixedly connected between the inner end spherical rod and the second pull rod, the inner end spherical clamping groove is arranged on the first pull rod, the inner end spherical rod is connected with the inner end spherical clamping groove in a matched mode, the.

As a further optimization of the technical scheme, the invention discloses intelligent steel bar rust removal equipment, which comprises a power source, a power underframe, a driving sliding frame, an output rod, a matching sleeve, a first friction wheel, a second friction wheel, a first transmission rod, a first bevel gear boss, a second bevel gear, a middle-end sliding sleeve, a deflector rod, an input motor, an input bevel gear, a second bevel gear boss, a transmission rod boss and a boss matching groove, wherein the output rod is rotatably connected with the power underframe, the matching sleeve is rotatably connected with the output rod in a sliding matching way, the matching sleeve is rotatably connected with the driving sliding frame, the driving sliding frame is rotatably connected with the power underframe, the first friction wheel is fixedly connected with the matching sleeve, the first friction wheel is in friction transmission with the second friction wheel, the second friction wheel is fixedly connected with the first transmission rod, the first transmission rod is rotatably connected with the power underframe, the boss is fixedly connected with the first transmission rod, and the first, the bevel gear transmission device comprises a first bevel gear boss and a second bevel gear boss, wherein the first bevel gear boss and the second bevel gear boss are fixedly connected with the first bevel gear and the second bevel gear respectively, a boss matching groove is formed in the inner end of a middle-end sliding sleeve, a transmission rod boss is connected with the boss matching groove in a matching mode, a shifting rod is connected with the middle-end sliding sleeve in a matching mode, an input motor is fixedly connected with a power chassis, an input bevel gear is fixedly connected with the input motor, the input bevel gear is in meshing transmission with the first bevel gear and the second bevel gear, the middle-end sliding sleeve is connected with the first bevel gear boss in a matching mode, the shifting rod is connected with a waist groove rod in a matching.

The intelligent steel bar rust removal equipment has the beneficial effects that:

according to the intelligent steel bar rust removing equipment, the input motor is started, the input bevel gear is further transferred to rotate, the first bevel gear and the second bevel gear are further driven to move through the input bevel gear, the initial position of the middle-end sliding sleeve is connected with the second bevel gear boss in a matched mode, the first transmission rod is further driven to rotate through the matched connection between the boss matching groove in the middle-end sliding sleeve and the transmission rod boss, the second friction wheel is further driven to rotate, the first friction wheel is further driven to rotate, the output rod is further driven to rotate, and power output through the output rod is further 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 first structural diagram of the rust removing assembly of the invention;

FIG. 4 is a schematic structural diagram II of the rust removing assembly of the invention;

FIG. 5 is a third structural schematic diagram of the rust removing assembly of the present invention;

FIG. 6 is a fourth structural schematic diagram of the rust removing assembly of the present invention;

FIG. 7 is a first structural view of the undercarriage assembly of the present invention;

FIG. 8 is a second schematic structural diagram of the undercarriage assembly of the present invention;

FIG. 9 is a first schematic view of the transition assembly of the present invention;

FIG. 10 is a second schematic view of the transition assembly of the present invention;

FIG. 11 is a third schematic view of the transition assembly of the present invention;

FIG. 12 is a fourth schematic view of the transition 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 view of the power source of the present invention.

In the figure: a derusting assembly 1; derusting the outer frame 1-1; 1-2 of a bevel gear sheave; 1-3 rectangular grooves; 1-4 of rollers; 1-5 of a belt wheel I; 1-6 parts of a first belt; a second belt wheel 1-7; 1-8 parts of a second belt; 1-9 parts of a buffer sleeve; 1-10 parts of a buffer sleeve II; 1-11 parts of a buffering push spring; a second buffer push spring 1-12; 1-13 of a first bracket; belt wheels III 1-14; 1-15 parts of middle-end slider; 1-16 of middle sliding column; middle end push spring 1-17; rollers 1-18; 1-19 parts of iron brush; 1-20 of inner end sliding column I; the inner end of the push spring I is 1-21; pulley four 1-22; 1-23 parts of bottom end bevel gear; 1-24 parts of lower end boss; a chassis assembly 2; a chassis body 2-1; an upper connecting rod 2-2; 2-3 of a first sliding chute; 2-4 of a second sliding chute; 2-5 of a connecting pin; a transition assembly 3; a transition underframe 3-1; a first transmission belt wheel 3-2; 3-3 of a connecting belt I; a second transmission belt wheel 3-4; 3-5 of an N-shaped frame; driving the first sliding block to 3-6; driving a second sliding block 3-7; 3-8 parts of an inner side clamping groove I; 3-9 parts of an inner clamping groove II; the inner end is clamped by 3-10; the inner end of the clamp pushes a spring I3-11; inner end clips II 3-12; the inner end of the clamp pushes a second spring 3-13; 3-14 parts of an arc-shaped sliding rod I; 3-15 parts of an arc slide bar push spring I; the first matching roller is 3-16; the first hinge rod is 3-17; 3-18 parts of a first tension spring; 3-19 arc slide bar II; 3-20 parts of arc slide bar push spring II; 3-21 parts of a second tension spring; a second hinge rod 3-22; a second matching roller 3-23; 3-24 parts of a first pull rod; 3-25 parts of a second pull rod; 3-26 parts of a waist groove rod; inner end spherical rods 3-27; the inner end of the push spring A3-28; 3-29 parts of spherical clamping groove at the inner end; 3-30 of a matching belt wheel; a power source 4; a power chassis 4-1; a drive carriage 4-2; an output rod 4-3; 4-4 of a matching sleeve; 4-5 parts of a first friction wheel; 4-6 parts of a second friction wheel; 4-7 of a first transmission rod; 4-8 parts of a first bevel gear; 4-9 parts of a first bevel gear boss; 4-10 parts of a second bevel gear; 4-11 of a middle sliding sleeve; 4-12 of a deflector rod; inputting motors 4-13; inputting 4-14 conical teeth; 4-15 parts of a second bevel gear boss; 4-16 parts of a boss of the transmission rod; the bosses engage the slots 4-17.

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 embodiment is described below with reference to fig. 1 to 15, and an intelligent steel bar rust removal device includes a rust removal assembly 1, an underframe assembly 2, a transition assembly 3, and a power source 4, where the rust removal assembly 1 is connected to the underframe assembly 2, the transition assembly 3 is connected to the underframe assembly 2, and the power source 4 is connected to the transition assembly 3.

The second embodiment is as follows:

the first embodiment is further described with reference to fig. 1-15, and the rust removing assembly 1 includes a rust removing outer frame 1-1, a bevel gear sheave 1-2, a rectangular groove 1-3, a roller 1-4, a pulley 1-5, a belt 1-6, a pulley two 1-7, a belt two 1-8, a buffer sleeve one 1-9, a buffer sleeve two 1-10, a buffer push spring one 1-11, a buffer push spring two 1-12, a bracket one 1-13, a pulley three 1-14, a middle end slider 1-15, a middle end sliding column 1-16, a middle end push spring 1-17, a roller 1-18, an iron 1-19, an inner end sliding column one 1-20, an inner end push brush spring one 1-21, a pulley four 1-22, 1-23 parts of bottom end conical teeth, 1-24 parts of lower end bosses, 1-2 parts of conical tooth grooved wheels, 1-1 parts of derusting outer frames, 1-3 parts of rectangular grooves, 1-2 parts of conical tooth grooved wheels, 1-4 parts of rollers, 1-1 parts of derusting outer frames, 1-5 parts of belt wheels, 1-1 parts of derusting outer frames, 1-7 parts of belt wheels, 1-6 parts of belts, 1-7 parts of belt wheels, 1-8 parts of belt wheels, 1-14 parts of belt wheels and 1-22 parts of belt wheels, 1-9 parts of buffer sleeve pipes, 1-10 parts of buffer sleeve pipes, 1-11 parts of buffer push springs and 1-1 parts of derusting outer frames, 1-1 parts of derusting outer frames and 1-1 parts, The two buffering push springs 1-12 are arranged at two ends of the two buffering sleeves 1-10, the two buffering push springs 1-12 are connected with the two buffering sleeves 1-10 in a sleeved mode, the two buffering sleeves 1-10 are connected with the first support 1-13 in an articulated mode, the first support 1-13 is connected with the derusting outer frame 1-1 in a rotating mode, the middle end sliding columns 1-16 are fixedly connected with the first support 1-13, the middle end sliding columns 1-15 are connected with the middle end sliding columns 1-16 in a sliding mode, the middle end push springs 1-17 are connected with the middle end sliding columns 1-16 in a sleeved mode, the belt pulleys three 1-14 are connected with the middle end sliding columns 1-15 in a rotating mode, the rollers 1-18 are connected with the first support 1-13 in a rotating mode, the belt pulleys four 1-22 are fixedly connected with the rollers 1-18, and the inner end sliding columns 1-20 are, the inner end push springs I1-21 are connected with the inner end sliding columns I1-20 in a sleeved mode, the iron brushes 1-19 are connected with the inner end sliding columns I1-20 in a sliding mode, the inner end push springs I1-21 are fixedly connected between the iron brushes 1-19 and the rollers 1-18, the lower end bosses 1-24 are fixedly connected with the derusting outer frame 1-1, the bottom end bevel teeth 1-23 are fixedly connected with the belt pulleys I1-5, and the bottom end bevel teeth 1-23 are in meshing transmission with the bevel gear grooved wheels 1-2.

The third concrete implementation mode:

this embodiment will be described with reference to fig. 1 to 15, which further illustrate the first embodiment, the chassis assembly 2 comprises a chassis body 2-1, upper side connecting rods 2-2, a first sliding groove 2-3, a second sliding groove 2-4 and connecting pins 2-5, wherein the first sliding groove 2-3 and the second sliding groove 2-4 are all arranged on the chassis body 2-1, the number of the rust removal assemblies 1 is two, the upper side connecting rods 2-2 are fixedly connected between the two rust removal outer frames 1-1, the number of the connecting pins 2-5 is multiple, the connecting pins 2-5 are all fixedly connected with the chassis body 2-1, lower end bosses 1-24 are attached to the chassis body 2-1, rectangular grooves 1-3 are connected with the connecting pins 2-5 in a matched mode, and rollers 1-4 are arranged in the first sliding grooves 2-3.

The fourth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-15, and the first embodiment is further described, wherein the transition assembly 3 comprises a transition underframe 3-1, a first transmission belt wheel 3-2, a first connecting belt 3-3, a second transmission belt wheel 3-4, an N-shaped frame 3-5, a first driving slider 3-6, a second driving slider 3-7, a first inside clamping groove 3-8, a second inside clamping groove 3-9, a first inside clip 3-10, a first inside clip pushing spring 3-11, a second inside clip 3-12, a second inside clip pushing spring 3-13, a first arc-shaped slide rod 3-14, a first arc-shaped slide rod pushing spring 3-15, a first matching roller 3-16, a first hinge rod 3-17, a first tension spring 3-18, a second arc-shaped slide rod 3-19, a second arc-shaped slide rod pushing spring 3-20, a second connecting belt 3-1, a second connecting, A tension spring II 3-21, a hinge rod II 3-22, a matching roller II 3-23, a pull rod I3-24, a pull rod II 3-25, a waist groove rod 3-26, an inner end spherical rod 3-27, an inner end push spring A3-28, an inner end spherical clamping groove 3-29, a matching belt wheel 3-30, a transmission belt wheel I3-2, a transmission belt wheel II 3-4 and a transition underframe 3-1 are rotatably connected, the transmission belt wheel I3-2 is arranged between the transmission belt wheel I3-2 and the transmission belt wheel II 3-4, an N-shaped frame 3-5 is fixedly connected with the transition underframe 3-1, an inner side clamping groove I3-8 and an inner side clamping groove II 3-9 are arranged at the inner end of the N-shaped frame 3-5, a driving slide block I3-6, a driving slide block II 3-7 and the N-shaped frame 3-5 are slidably connected, the inner end clamp I3-10 is connected with the driving slide block I3-6 in a sliding mode, the inner end clamp push spring I3-11 is arranged between the inner end clamp I3-10 and the driving slide block I3-6, the inner end clamp I3-10 is connected with the inner side clamping groove I3-8 in a matching mode, the inner end clamp II 3-12 is connected with the driving slide block II 3-7 in a sliding mode, the inner end clamp push spring II 3-13 is arranged between the inner end clamp II 3-12 and the driving slide block II 3-7, the inner end clamp II 3-12 is connected with the inner side clamping groove II 3-9 in a matching mode, the arc-shaped slide rod I3-14 is connected with the driving slide block I3-6 in a sliding mode, the arc-shaped slide rod push spring I3-15 is connected with the arc-shaped slide rod I3-14 in a sleeving mode, a tension spring I3-18 is connected between a hinge rod I3-17 and a driving slide block I3-6, a matching roller I3-16 is rotatably connected with the driving slide block I3-6, a matching roller I3-16 is connected with an arc slide rod I3-14 in a matching way, an arc slide rod II 3-19 is slidably connected with a driving slide block II 3-7, an arc slide rod push spring II 3-20 is connected with an arc slide rod II 3-19 in a sleeved way, a tension spring II 3-21 is connected between a driving slide block II 3-7 and a hinge rod II 3-22, a hinge rod II 3-22 is connected with a driving slide block II 3-7 in a hinged way, a matching roller II 3-23 is rotatably connected with a hinge rod II 3-22, a pull rod I3-24 is hinged with the hinge rod I3-17, a pull rod II 3-25 is hinged with the hinge rod II 3-22, the waist groove rod 3-26 is fixedly connected with the pull rod II 3-25, the inner end spherical rod 3-27 is connected with the pull rod II 3-25 in a sliding mode, the inner end push spring A3-28 is arranged and fixedly connected between the inner end spherical rod 3-27 and the pull rod II 3-25, the inner end spherical clamping groove 3-29 is arranged on the pull rod I3-24, the inner end spherical rod 3-27 is connected with the inner end spherical clamping groove 3-29 in a matching mode, the matching belt wheel 3-30 is arranged at the inner end of the connecting belt I3-3, the matching belt wheel 3-30 is fixedly connected with the conical tooth grooved wheel 1-2, and the underframe body 2-1 is fixedly connected with the transition underframe 3-1.

The fifth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-15, the power source 4 includes a power chassis 4-1, a driving carriage 4-2, an output rod 4-3, a matching sleeve 4-4, a friction wheel I4-5, a friction wheel II 4-6, a transmission rod I4-7, a bevel gear I4-8, a bevel gear boss I4-9, a bevel gear II 4-10, a middle end sliding sleeve 4-11, a shift lever 4-12, an input motor 4-13, an input bevel gear 4-14, a bevel gear boss II 4-15, a transmission rod boss 4-16 and a boss matching groove 4-17, the output rod 4-3 is rotatably connected with the power chassis 4-1, the matching sleeve 4-4 is slidably connected with the output rod 4-3, the matching sleeve 4-4 is rotationally connected with the driving sliding frame 4-2, the driving sliding frame 4-2 is in sliding matching connection with the power underframe 4-1, the friction wheel I4-5 is fixedly connected with the matching sleeve 4-4, the friction wheel I4-5 is in friction transmission with the friction wheel II 4-6, the friction wheel II 4-6 is fixedly connected with the transmission rod I4-7, the transmission rod I4-7 is rotationally connected with the power underframe 4-1, the transmission rod boss 4-16 is fixedly connected with the transmission rod I4-7, the bevel gear I4-8 and the bevel gear II 4-10 are in matching connection with the transmission rod I4-7, the bevel gear boss I4-9 and the bevel gear boss II 4-15 are respectively and fixedly connected with the bevel gear I4-8 and the bevel gear II 4-10, the boss matching groove 4-17 is arranged at the inner end of the middle-end sliding sleeve 4-11, a boss 4-16 of a transmission rod is connected with a boss matching groove 4-17 in a matching manner, a deflector rod 4-12 is connected with a middle-end sliding sleeve 4-11 in a matching manner, an input motor 4-13 is fixedly connected with a power underframe 4-1, an input bevel gear 4-14 is fixedly connected with the input motor 4-13, the input bevel gear 4-14 is in meshing transmission with a bevel gear I4-8 and a bevel gear II 4-10, the middle-end sliding sleeve 4-11 is connected with a bevel gear boss I4-9 in a matching manner, the deflector rod 4-12 is connected with a waist groove rod 3-26 in a matching manner, an output rod 4-3 is fixedly connected with a transmission belt wheel II 3-4, and the power underframe 4-1 is fixedly connected with a transition underframe 3-1;

the input motor 4-13 is started, the input bevel gear 4-14 is transferred to rotate, the input bevel gear 4-14 drives the bevel gear I4-8 and the bevel gear II 4-10 to move, the initial position of the middle-end sliding sleeve 4-11 is in fit connection with the bevel gear boss II 4-15, the transmission rod I4-7 is driven to rotate through the fit connection between the boss fit groove 4-17 on the middle-end sliding sleeve 4-11 and the transmission rod boss 4-16, the friction wheel II 4-6 is driven to rotate, the friction wheel I4-5 is driven to rotate, the output rod 4-3 is driven to rotate, and power output is facilitated through the output rod 4-3.

The invention discloses intelligent steel bar rust removal equipment, which has the working principle that: when the rust-removing device is used, the bevel gear grooved wheels 1-2 rotate to drive the bottom bevel gears 1-23 to rotate, further drive the belt wheels 1-5 to rotate, further drive the belt wheels 1-6 to move, further drive the belt wheels 1-7 to rotate, further drive the belt wheels 1-22 to rotate through the belts 1-8, further drive the rollers 1-18 to rotate, further drive the iron brushes 1-19 to move, further contact the steel bars to be treated through the iron brushes 1-19, and further realize the treatment of rust at the outer ends of the steel bars; when the rollers 1-18 are in contact with the steel bars, the rollers 1-18 are reacted by the steel bars to push the supports 1-13 to rotate around the hinge points with the derusting outer frame 1-1, so that the belts 1-8 deform, at the moment, the relative sliding between the middle end sliders 1-15 and the middle end sliding columns 1-16 is realized, the deformation of the belts 1-8 is compensated through the belt pulleys three 1-14 on the middle end sliders 1-15, the belts 1-8 are tensioned, and meanwhile, the springs 1-11 are pushed through buffering; the buffer push springs II 1-12 act on the elastic force of the buffer sleeves I1-9 and the buffer sleeves II 1-10 to further hinder the pushing of the supports I1-13 to rotate around the hinge point of the derusting outer frame 1-1, so that the iron brushes 1-19 are conveniently attached to the outer sides of the steel bars to be processed; when the bevel gear grooved wheel 1-2 rotates, the connecting pin 2-5 is connected with the rectangular groove 1-3 in a matched mode, when the bevel gear grooved wheel 1-2 rotates, the derusting outer frame 1-1 is driven to move along the underframe body 2-1, and meanwhile the connecting pin 2-5 is connected with the rectangular groove 1-3 in a matched mode through the boss 1-24 at the lower end of the derusting outer frame and the underframe body 2-1 in a matched mode; when the derusting outer frame 1-1 moves along the underframe body 2-1, the bevel gear grooved pulley 1-2 drives the matching belt wheel 3-30 to move in the connecting belt I3-3 so as to change the position of the matching belt wheel 3-30 in the connecting belt I3-3, when the matching belt wheel 3-30 is in contact with the arc slide bar I3-14, the arc slide bar I3-14 is pushed to slide towards the rear side, the matching roller I3-16 drives the hinge rod I3-17 to rotate towards the rear side along the driving slide block I3-6, the matching connection of the inner end spherical clamping groove 3-29 on the pull rod I3-24 and the inner end spherical rod 3-27 is adopted, the pull rod II 3-25 is driven to move towards the rear side simultaneously, and the hinge rod II 3-22 is driven to rotate around the driving slide block II 3-7 towards the rear side, so that the second matching rollers 3-23 are attached to the second arc-shaped sliding rods 3-19, the deflector rods 4-12 are driven by the waist-groove rods 3-26, the deflector rods 4-12 drive the middle-end sliding sleeves 4-11 to move backwards along the first transmission rods 4-7, the middle-end sliding sleeves 4-11 are separated from the second bevel gear bosses 4-15, the middle-end sliding sleeves 4-11 are connected with the first bevel gear bosses 4-9 in a matching mode, the transmission of the input bevel gears 4-14 and the second bevel gears 4-10 is disabled, the input bevel gears 4-14 and the first bevel gears 4-8 are in meshing transmission, the rotating direction of the first transmission rods 4-7 is changed, and the first friction wheels 4-5 are driven by the second friction wheels 4-6, then the output rod 4-3 is driven to rotate by the matching sleeve 4-4, so that the output rod 4-3 rotates reversely, the transmission belt wheel II 3-4 is driven by the output rod 4-3 and the connection belt I3-3 rotates reversely, the transmission belt wheel I3-2 is driven by the connection belt I3-3 to rotate reversely, the rust removal assembly 1 is driven to move forwards by the transmission belt wheel I3-2, when the transmission belt wheel I3-2 is in contact with the arc slide bar II 3-19 and drives the arc slide bar II 3-19 to slide forwards along the driving slide block II 3-7, the matching roller II 3-23 is driven by the arc slide bar II 3-19 to move, and the hinging rod II 3-22 is driven to swing forwards along the driving slide block II 3-7 by the matching roller II 3-23, the second pull rod 3-25 is driven to move forwards through the second driving slide block 3-7, the deflector rod 4-12 is driven through the waist-shaped groove rod 3-26, the deflector rod 4-12 drives the middle-end sliding sleeve 4-11 to move forwards along the first driving rod 4-7, the middle-end sliding sleeve 4-11 is separated from the first bevel gear boss 4-9, the middle-end sliding sleeve 4-11 is connected with the second bevel gear boss 4-15 in a matched mode, the input bevel gear 4-14 is in meshed transmission with the second bevel gear 4-10, transmission between the input bevel gear 4-14 and the first bevel gear 4-8 is disabled, the rotating direction of the first driving rod 4-7 is changed, and the first friction wheel 4-5 is driven through the second friction wheel 4-6, the output rod 4-3 is driven to rotate through the matching sleeve 4-4, so that the output rod 4-3 rotates reversely, the transmission belt wheel II 3-4 is driven through the output rod 4-3, the connection belt I3-3 is driven to rotate reversely again, the transmission belt wheel I3-2 is driven through the connection belt I3-3 to rotate reversely, the rust removal assembly 1 is driven to move towards the rear side through the transmission belt wheel I3-2, and the rust removal assembly 1 is driven to move towards the rear side through the transmission belt wheel I3-2, so that the cycle of a complete process is completed; the first sliding block 3-6 can be driven to slide along the N-shaped frame 3-5; driving the second slide block 3-7 to drive the first slide block 3-6; the distance between the second driving sliding blocks 3-7 is changed, so that the reciprocating movement distance of the derusting assembly 1 is changed, and the heavy derusting treatment on a certain section of the steel bar is realized; when the first sliding block is driven by 3-6; when the distance between the driving sliding blocks II 3-7 changes, the distance between the pull rods I3-24 and the distance between the pull rods II 3-25 change simultaneously, so that one displacement release is facilitated; the input motor 4-13 is started, the input bevel gear 4-14 is transferred to rotate, the input bevel gear 4-14 drives the bevel gear I4-8 and the bevel gear II 4-10 to move, the initial position of the middle-end sliding sleeve 4-11 is in fit connection with the bevel gear boss II 4-15, the transmission rod I4-7 is driven to rotate through the fit connection between the boss fit groove 4-17 on the middle-end sliding sleeve 4-11 and the transmission rod boss 4-16, the friction wheel II 4-6 is driven to rotate, the friction wheel I4-5 is driven to rotate, the output rod 4-3 is driven to rotate, and power output is facilitated through the output rod 4-3.

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 an intelligent reinforcing bar rust cleaning equipment, includes rust cleaning assembly (1), chassis assembly (2), transition assembly (3), power supply (4), its characterized in that: the rust removal assembly (1) is connected with the bottom frame assembly (2), the transition assembly (3) is connected with the bottom frame assembly (2), and the power source (4) is connected with the transition assembly (3).

2. The intelligent steel bar rust removal equipment of claim 1, wherein: the derusting assembly (1) comprises a derusting outer frame (1-1), a bevel gear grooved pulley (1-2), a rectangular groove (1-3), a roller (1-4), a belt wheel I (1-5), a belt wheel I (1-6), a belt wheel II (1-7), a belt wheel II (1-8), a buffer sleeve I (1-9), a buffer sleeve II (1-10), a buffer push spring I (1-11), a buffer push spring II (1-12), a support I (1-13), a belt wheel III (1-14), a middle-end slider (1-15), a middle-end sliding column (1-16), a middle-end push spring (1-17), a roller (1-18), an iron brush (1-19), an inner-end sliding column I (1-20), an inner-end push spring I (1-21), A fourth belt wheel (1-22), bottom end bevel teeth (1-23) and a lower end boss (1-24), wherein a bevel gear sheave (1-2) is rotationally connected with a derusting outer frame (1-1), a rectangular groove (1-3) is arranged on the bevel gear sheave (1-2), a roller (1-4) is rotationally connected with the derusting outer frame (1-1), a first belt wheel (1-5) is rotationally connected with the derusting outer frame (1-1), a second belt wheel (1-7) is rotationally connected with the derusting outer frame (1-1), a first belt (1-6) is connected between the first belt wheel (1-5) and the second belt wheel (1-7), a second belt (1-8) is connected between the second belt wheel (1-7), the third belt wheel (1-14) and the fourth belt wheel (1-22), a first buffer sleeve (1-9) is hinged with the derusting outer frame (1-1), the buffer sleeve I (1-9) is connected with the buffer sleeve II (1-10) in a sliding manner, the buffer push spring I (1-11) and the buffer push spring II (1-12) are arranged at two ends of the buffer sleeve II (1-10), the buffer push spring II (1-12) is connected with the buffer sleeve II (1-10) in a sleeved manner, the buffer sleeve II (1-10) is hinged with the support I (1-13), the support I (1-13) is rotationally connected with the derusting outer frame (1-1), the middle end sliding column (1-16) is fixedly connected with the support I (1-13), the middle end sliding column (1-15) is connected with the middle end sliding column (1-16) in a sliding manner, the middle end push spring (1-17) is connected with the middle end sliding column (1-16) in a sleeved manner, the belt wheel III (1-14) is rotationally connected with the middle end sliding column (1-15), the roller (1-18) is rotatably connected with the support I (1-13), the belt wheel IV (1-22) is fixedly connected with the roller (1-18), the inner end sliding column I (1-20) is fixedly connected with the roller (1-18), the inner end push spring I (1-21) is connected with the inner end sliding column I (1-20) in a sleeved mode, the iron brush (1-19) is connected with the inner end sliding column I (1-20) in a sliding mode, the inner end push spring I (1-21) is fixedly connected between the iron brush (1-19) and the roller (1-18), the lower end boss (1-24) is fixedly connected with the derusting outer frame (1-1), the bottom end conical teeth (1-23) are fixedly connected with the belt wheel I (1-5), and the bottom end conical teeth (1-23) are in meshing transmission with the conical teeth grooved pulley (1-2).

3. The intelligent steel bar rust removal equipment of claim 1, wherein: the underframe assembly (2) comprises an underframe body (2-1), an upper side connecting rod (2-2), a first sliding groove (2-3), a second sliding groove (2-4) and a connecting pin (2-5), the first sliding groove (2-3) and the second sliding groove (2-4) are arranged on the chassis body (2-1), the number of the rust removing assemblies (1) is two, the upper side connecting rod (2-2) is fixedly connected between the two rust removing outer frames (1-1), the number of the connecting pins (2-5) is multiple, the connecting pins (2-5) are fixedly connected with the chassis body (2-1), the lower end boss (1-24) is attached to the chassis body (2-1), the rectangular groove (1-3) is connected with the connecting pins (2-5) in a matched mode, and the roller (1-4) is arranged in the first sliding groove (2-3).

4. The intelligent steel bar rust removal equipment of claim 1, wherein: the transition assembly (3) comprises a transition underframe (3-1), a transmission belt wheel I (3-2), a connecting belt I (3-3), a transmission belt wheel II (3-4), an N-shaped frame (3-5), a driving slide block I (3-6), a driving slide block II (3-7), an inner side clamping groove I (3-8), an inner side clamping groove II (3-9), an inner end clamp I (3-10), an inner end clamp push spring I (3-11), an inner end clamp II (3-12), an inner end clamp push spring II (3-13), an arc slide rod I (3-14), an arc slide rod push spring I (3-15), a matching roller I (3-16), a hinge rod I (3-17), a tension spring I (3-18), an arc slide rod II (3-19), A second arc-shaped sliding rod push spring (3-20), a second tension spring (3-21), a second hinge rod (3-22), a second matching roller (3-23), a first pull rod (3-24), a second pull rod (3-25), a waist groove rod (3-26), an inner end spherical rod (3-27), an inner end push spring A (3-28), an inner end spherical clamping groove (3-29) and a matching belt wheel (3-30), a first transmission belt wheel (3-2), a second transmission belt wheel (3-4) are rotationally connected with a transition underframe (3-1), the first transmission belt wheel (3-2) is arranged between the first transmission belt wheel (3-2) and the second transmission belt wheel (3-4), an N-shaped frame (3-5) is fixedly connected with the transition underframe (3-1), and the first inner side clamping groove (3-8), The inner side clamping groove II (3-9) is arranged at the inner end of the N-shaped frame (3-5), the driving slide block I (3-6), the driving slide block II (3-7) and the N-shaped frame (3-5) are connected in a sliding mode, the inner end clamp I (3-10) is connected with the driving slide block I (3-6) in a sliding mode, the inner end clamp push spring I (3-11) is arranged between the inner end clamp I (3-10) and the driving slide block I (3-6), the inner end clamp I (3-10) is connected with the inner side clamping groove I (3-8) in a matching mode, the inner end clamp II (3-12) is connected with the driving slide block II (3-7) in a sliding mode, the inner end clamp push spring II (3-13) is arranged between the inner end clamp II (3-12) and the driving slide block II (3-7), the inner end clamp II (3-12) is connected with the inner side clamping groove II, the arc-shaped sliding rod I (3-14) is connected with the driving sliding block I (3-6) in a sliding mode, the arc-shaped sliding rod I (3-15) is connected with the arc-shaped sliding rod I (3-14) in a sleeved mode, the hinge rod I (3-17) is connected with the driving sliding block I (3-6) in a rotating mode, the tension spring I (3-18) is connected between the hinge rod I (3-17) and the driving sliding block I (3-6), the matching roller I (3-16) is connected with the driving sliding block I (3-6) in a rotating mode, the matching roller I (3-16) is connected with the arc-shaped sliding rod I (3-14) in a matching mode, the arc-shaped sliding rod II (3-19) is connected with the driving sliding block II (3-7) in a sliding mode, the arc-shaped sliding rod II (3-20) is connected with the arc-shaped sliding rod II (3-19) in a sleeved mode, and the tension spring II (3) A second hinged rod (3-22) is hinged with a second driving slide block (3-7), a second matching roller (3-23) is rotatably connected with the second hinged rod (3-22), a first pull rod (3-24) is hinged with a first hinged rod (3-17), a second pull rod (3-25) is hinged with the second hinged rod (3-22), a waist groove rod (3-26) is fixedly connected with the second pull rod (3-25), an inner end spherical rod (3-27) is slidably connected with the second pull rod (3-25), an inner end push spring A (3-28) is arranged and fixedly connected between the inner end spherical rod (3-27) and the second pull rod (3-25), an inner end spherical clamping groove (3-29) is arranged on the first pull rod (3-24), the inner end spherical rod (3-27) is matched and connected with the inner end spherical clamping groove (3-29), the matching belt wheel (3-30) is arranged at the inner end of the connecting belt I (3-3), the matching belt wheel (3-30) is fixedly connected with the bevel gear grooved wheel (1-2), and the underframe body (2-1) is fixedly connected with the transition underframe (3-1).

5. The intelligent steel bar rust removal equipment of claim 1, wherein: the power source (4) comprises a power chassis (4-1), a driving sliding frame (4-2), an output rod (4-3), a matching sleeve (4-4), a friction wheel I (4-5), a friction wheel II (4-6), a transmission rod I (4-7), a bevel gear I (4-8), a bevel gear boss I (4-9), a bevel gear II (4-10), a middle-end sliding sleeve (4-11), a deflector rod (4-12), an input motor (4-13), an input bevel gear (4-14), a bevel gear boss II (4-15), a transmission rod boss (4-16) and a boss matching groove (4-17), the output rod (4-3) is rotatably connected with the power chassis (4-1), and the matching sleeve (4-4) is slidably matched and connected with the output rod (4-3), the driving sliding frame (4-2) is rotatably connected with the matching sleeve (4-4), the driving sliding frame (4-2) is connected with the power underframe (4-1) in a sliding fit manner, the first friction wheel (4-5) is fixedly connected with the matching sleeve (4-4), the first friction wheel (4-5) is in friction transmission with the second friction wheel (4-6), the second friction wheel (4-6) is fixedly connected with the first transmission rod (4-7), the first transmission rod (4-7) is rotatably connected with the power underframe (4-1), the boss (4-16) of the transmission rod is fixedly connected with the first transmission rod (4-7), the first cone tooth (4-8), the second cone tooth (4-10) are in fit connection with the first transmission rod (4-7), and the first cone tooth boss (4-9) and the second cone tooth boss (4-15) are respectively connected with the first cone tooth (4-8), A second bevel gear (4-10) is fixedly connected, a boss matching groove (4-17) is arranged at the inner end of the middle-end sliding sleeve (4-11), a transmission rod boss (4-16) is matched and connected with the boss matching groove (4-17), a deflector rod (4-12) is matched and connected with the middle-end sliding sleeve (4-11), an input motor (4-13) is fixedly connected with a power chassis (4-1), an input bevel gear (4-14) is fixedly connected with the input motor (4-13), an input bevel gear (4-14) is meshed and transmitted with a first bevel gear (4-8) and a second bevel gear (4-10), the middle-end sliding sleeve (4-11) is matched and connected with a first bevel gear boss (4-9), the deflector rod (4-12) is matched and connected with a waist groove rod (3-26), an output rod (4-3) is fixedly connected with a second transmission belt wheel (3-4), the power underframe (4-1) is fixedly connected with the transition underframe (3-1).

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