CN114772414A - Equipment mold for special elevator parts and machining method - Google Patents

Abstract

The invention discloses an equipment mould for special elevator parts in the technical field of elevator guide shoe assembly. The elevator guide shoe comprises a die for assembling the elevator guide shoe, wherein the elevator guide shoe comprises a shoe base, a shoe groove, a guide wheel and a shoe lining, the elevator guide shoe further comprises a first screw for limiting the shoe lining to the inside of the shoe groove, a second screw for installing the shoe groove and the shoe lining in front of the shoe base and a third screw for installing the guide wheel in a clamping cavity formed between the shoe base and the shoe groove. Need not and go to observe the eyelet with eyes and align, directly let bootlace, boot groove and boots and base of a shoe dog support together, alright realize aliging, when fixing two parts with the screw, the workman need not to vacate a hand and goes to hold up these two parts steady, when adding new part on the basis of the assembly, need not to readjust the position of assembly.

Description

Equipment mold and machining method for special elevator parts

Technical Field

The invention relates to the technical field of elevator guide shoe assembly, in particular to an equipment mold and a processing method of special elevator parts.

Background

As parts of an elevator, an elevator guide shoe is generally assembled from parts such as a shoe base, a shoe groove, a shoe liner, and a guide pulley. Therefore, the profile of the elevator shoe is not a regular square.

At present, the assembly operation of the guide shoe and the elevator is generally carried out manually. And a common way is to place each part for assembling the elevator guide shoe in different storage boxes according to its kind, and then place the storage boxes containing the parts on a work table, and a worker picks up the corresponding parts according to the assembling steps and assembles the picked-up parts together step by step on a flat table top of the work table. This conventional assembly method has the following disadvantages:

firstly, a worker performs an assembling operation on a flat table top, and the worker is required to align holes of two parts to be assembled together so as to mount the two parts together by screws, the worker is required to adjust the relative positions of the two parts back and forth by hand and observe whether the holes are aligned or not by eyes. This approach is time consuming for unskilled workers.

And secondly, when a worker carries out assembly operation on the flat desktop and needs to fix the two parts by using screws, the worker needs to vacate one hand to stably support the two parts so as to prevent the two parts from deviating in the process of mounting the screws and further cause the screws to deviate from the expected mounting positions. This approach is cumbersome for unskilled workers to install the screws.

And thirdly, in the process of assembling on the flat desktop by a worker, when one part is added, the position relation between the assembling body and the newly added part needs to be readjusted so as to install the two groups together. This method is time-consuming for unskilled workers to adjust the positions of the assembly and parts back and forth, and is not favorable for improving the efficiency of the assembly operation.

Based on the equipment mould and the processing method, the invention designs the equipment mould of the special elevator part and the processing method so as to solve the problems.

Disclosure of Invention

The invention aims to provide an equipment die and a processing method for special elevator parts, and aims to solve the problems that the traditional assembling mode of an elevator guide shoe in the background art is time-consuming for unskilled workers in operation, troublesome in screw installation, time-consuming in back and forth adjustment of the positions of an assembling body and parts and unfavorable for improving the efficiency of assembling operation.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides an equipment mould of special elevator spare part, leads boots including the elevator, still includes the mould that is used for leading boots to the elevator and assembles the operation.

The elevator guide shoe comprises a shoe base, a shoe groove, a guide wheel and a shoe lining, and further comprises a first screw for limiting the shoe lining in the shoe groove, a second screw for installing the shoe groove and the shoe lining right in front of the shoe base and a third screw for installing the guide wheel in a clamping cavity formed between the shoe base and the shoe groove.

The die comprises a first die set and a second die set.

The first module comprises a base used for being stably placed on a desktop, a rotating seat which can rotate on the base and is used for installing the second module and a cushion seat used for placing the guide shoes of the elevator, and the first module further comprises a fourth screw used for fixing the cushion seat on the top of the rotating seat.

The second module comprises a push rod manually pushed to move up and down, a hinged support moving up and down along with the push rod, a hinged cylinder hinged with the hinged support, a hinged support driven by the hinged cylinder and a top pile driven by the hinged support, and further comprises a fifth screw for fixing the push rod in front of the hinged support, a sixth screw for hinging the hinged support and the hinged cylinder and a seventh screw for mounting the hinged support on the rotary support.

Preferably, the shoe base is provided with a first hole for mounting a second screw and a second hole for mounting a third screw.

And a third hole for mounting the first screw, a fourth hole which can be aligned with the second hole and is used for mounting the third screw and a fifth hole which can be aligned with the first hole and is used for mounting the second screw are formed in the boot groove.

The guide wheel comprises a wheel body, a first bearing arranged in the inner cavity of the wheel body and a positioning cylinder arranged in a shaft hole of the first bearing, and a sixth hole which can be aligned with the second hole and the fourth hole and is used for mounting a third screw is formed in the middle of the positioning cylinder.

And a hole seven which can be aligned with the three phases of the holes and is used for mounting a screw I and a hole eight which can be aligned with the hole five and is used for mounting a screw II are formed in the shoe liner.

Preferably, the base comprises a base body and a second bearing, and a hole nine for mounting the second bearing is formed in the middle of the base body.

Preferably, the swivel mount includes swivel mount body, the first swivel mount that welds on swivel mount body middle part roof, the swivel mount hinge lug of welding on swivel mount stand first middle part antetheca, the swivel mount stand second that welds on swivel mount body front portion roof and the pivot of welding on swivel mount body middle part diapire.

The novel bearing is characterized in that the rotary seat body is arranged right above the base body, two empty grooves used for placing top piles are formed in the rotary seat stand platform I, ten holes used for mounting screws IV are further uniformly formed in the top of the rotary seat stand platform I, eleven holes used for mounting screws VII are formed in the rotary seat hinge lug, two sliding grooves used for placing hinge seats and two open grooves I used for limiting the push rod are formed in the rotary seat stand platform II, and the rotary shaft is mounted in a shaft hole of the bearing II.

Preferably, the pad seat comprises a pad seat body, a pad seat stop block welded at the left end of the pad seat body and a pad seat ear block welded at the right end of the pad seat body.

The base is arranged at the top of the first rotating seat stand, two holes twelve which are respectively aligned with two empty grooves on the first rotating seat stand are formed in the base body of the base, the holes twelve are aligned with the holes eight, and the stop block of the base and the ear block of the base are respectively provided with a hole thirteen which is aligned with the holes ten and is used for mounting a screw four.

Preferably, the push rod comprises a push rod body pushed by hand, and a spring, a ball and a caulking cover which are arranged inside the push rod body.

The front wall at the left end and the right end of the push rod body is provided with fourteen holes, the rear wall at the left end and the right end of the push rod body is provided with fifteen holes communicated with the fourteen holes and used for inserting the front end of the hinged support, and the rear wall at the middle of the push rod body is provided with sixteen holes used for installing the embedded cover and seventeen holes communicated with the sixteen holes and used for installing the spring and the ball.

The spring is located in front of the ball, the left side and the right side of the embedding cover are provided with notches, and the middle of the embedding cover is provided with eighteen holes.

Preferably, the hinge base is provided with nineteen holes which can be aligned with the fourteen holes and are used for mounting a screw fifthly, two notches which can move up and down along the sliding groove, three notches for mounting the hinge barrel and twenty holes for mounting a screw sixteenth.

Preferably, the hinge barrel comprises a hinge barrel body and a hinge barrel lug welded at the front end of the hinge barrel body and used for being inserted into the third notch, and a twenty-one hole which can be aligned with the twenty hole and used for mounting the screw six is formed in the hinge barrel lug.

Preferably, the hinge frame comprises a first hinge frame body used for driving the top pile and a second hinge frame body driven by the hinge cylinder body.

One end of the first hinge frame body is a circular ring body, the other end of the first hinge frame body is a runway ring body, a ring cavity of the circular ring body of the first hinge frame body is aligned with the eleven holes and used for mounting a screw, one end of the second hinge frame body is welded to the circular ring body of the first hinge frame body, and the other end of the second hinge frame body is inserted into a barrel cavity of the barrel body.

Preferably, the top pile comprises a hinge rod for being hinged with the runway-shaped ring body of the hinge frame body I and a top rod welded in the middle of the hinge rod and used for being inserted into the twelve-hole cavity.

The axis of the ejector rod is perpendicular to the axis of the hinge rod, and the top end of the ejector rod is hexagonal prism-shaped.

The technical scheme provided by the invention also comprises a processing method for performing group operation on the elevator guide shoe by the equipment, which comprises the following specific steps:

and S1, mounting the second screw in the hole cavity of the twelve hole, and mounting the shoe liner on the shoe seat body.

S2, assembling the shoe groove and the shoe liner together by a first screw to form a first assembly.

And S3, assembling the shoe base and the assembly formed in the S2 together by using the second screw and the matched nut to form a second assembly.

And S4, assembling the guide wheel and the assembly formed in the step S3 together by using a third screw to form the elevator guide shoe.

Compared with the prior art, the invention has the beneficial effects that:

first, the present invention allows alignment to be achieved by directly abutting the bootie, boot channel and boot to the shoe block by the shoe block without the need to observe with eyes whether the eyelets are aligned or not by applying the shoe block.

And secondly, when the two parts are fixed by screws through the application of the cushion seat and the module II, workers do not need to give out one hand to support and stabilize the two parts.

And thirdly, through the application of the cushion seat and the module II, when a new part is added on the basis of the combined body, the position of the combined body does not need to be readjusted.

Of course, it is not necessary for any product to practice the invention to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic perspective view of the present invention;

fig. 2 is a front right top view of an elevator guide shoe of the present invention;

FIG. 3 is a right rear plan view of an elevator guide shoe of the present invention;

FIG. 4 is a front right top view of the boot of the present invention;

FIG. 5 is a rear right top view of the boot of the present invention;

FIG. 6 is a front right top view of the boot groove of the present invention;

FIG. 7 is a cross-sectional view of the invention of FIG. 6;

FIG. 8 is a front right top view of the idler of the present invention;

FIG. 9 is a front right top view of the bootie of the present invention;

FIG. 10 is a cross-sectional view of the invention of FIG. 9;

FIG. 11 is a front right plan view of the mold of the present invention;

FIG. 12 is an exploded front right side view of a first module of the present invention;

FIG. 13 is a front right top view of the base of the present invention;

FIG. 14 is a front right top view of the swivel base of the present invention;

FIG. 15 is a front right bottom view of the swivel base of the present invention;

FIG. 16 is a front right top view of the shoe of the present invention;

FIG. 17 is a front right bottom view of the shoe of the present invention;

FIG. 18 is a right front plan view of a second module of the present invention;

FIG. 19 is an exploded front right side elevational view of the push rod of the present invention;

FIG. 20 is an exploded rear right side view of the push rod of the present invention;

FIG. 21 is a front right top view of the anchor of the present invention;

FIG. 22 is a rear right bottom view of the free bearing of the present invention;

FIG. 23 is a front right top view of the hinge barrel of the present invention;

FIG. 24 is a right rear plan view of the hinge barrel of the present invention;

FIG. 25 is a front right top view of the hinge bracket of the present invention;

FIG. 26 is a front right top view of the stake of the present invention;

FIG. 27 is a schematic view of a feed screw used in the present invention;

fig. 28 is a first schematic view of the assembly of the elevator guide shoe on the mold in accordance with the present invention;

fig. 29 is a second schematic view of the elevator guide shoe of the present invention assembled on a mold;

fig. 30 is a third schematic view of the elevator guide shoe of the present invention assembled on a mold;

fig. 31 is a fourth schematic view of the elevator guide shoe of the present invention assembled on a mold;

fig. 32 is a fifth schematic view of the elevator guide shoe of the present invention assembled on a mold.

In the drawings, the components represented by the respective reference numerals are listed below:

1-an elevator guide shoe;

11-shoe seat, 01-hole I, 02-hole II;

12-boot groove, 03-hole three, 04-hole four, 05-hole five;

13-guide wheel, 1301-wheel body, 1302-bearing I, 1303-positioning cylinder and 06-hole six;

14-shoe liner, 07-hole seven, 08-hole eight;

001-screw one, 002-screw two, 003-screw three;

2-mould, 21-mould one, 22-mould two;

100-base, 110-base body, 101-hole nine and 120-bearing two;

200-rotation seat, 210-rotation seat body, 220-rotation seat stand I, 201-empty groove, 202-hole ten, 230-rotation seat hinge lug, 203-hole eleven, 240-rotation seat stand II, 204-sliding groove, 205-gap I and 250-rotating shaft;

300-cushion seat, 310-cushion seat body, 301-hole twelve, 320-cushion seat stop block, 330-cushion seat ear block, 302-hole thirteen;

400-push rod, 410-push rod body, 401-hole fourteen, 402-hole fifteen, 403-hole sixteen, 404-hole seventeen, 420-spring, 430-ball, 440-embedding cover, 405-notch and 406-hole eighteen;

500-free bearing, 501-nineteen holes, 502-two notches, 503-three notches and 504-twenty holes;

600-hinge cylinder, 610-hinge cylinder body, 620-hinge cylinder ear block, 601-hole twenty one;

700-hinge frame, 710-hinge frame body I, 720-hinge frame body II;

800-top pile, 810-hinge rod and 820-top rod;

004-screw four, 005-screw five, 006-screw six, 007-screw seven.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1, the present invention provides an equipment mold for special elevator components, which includes an elevator guide shoe 1 as a special elevator component and a mold 2 used for assembling the elevator guide shoe 1.

Referring to fig. 2, 3 and 27, the elevator guide shoe 1 according to the present invention includes a shoe support 11, a shoe groove 12, two guide rollers 13 and a shoe liner 14. In addition, the elevator guide shoe 1 further includes four screws one 001, two screws two 002, and two screws three 003. Wherein, every screw two 002 all is furnished with the nut of two adaptations.

Referring to fig. 4 and 5, the middle of the boot seat 11 provided by the present invention is a square plate-shaped metal plate, and two holes 01 having a circular through hole shape are respectively formed at the upper and lower portions of the metal plate, and the two holes 01 are arranged in an up-and-down symmetrical manner.

The upper part and the lower part of the shoe base 11 are respectively provided with a groove block in a square groove shape, the groove blocks at the upper part and the lower part of the shoe base 11 are integrally connected with a metal plate body in the middle of the shoe base 11, and the two groove blocks are arranged in a vertically symmetrical manner.

The left and right parts of the boot base 11 are respectively provided with an L-shaped corner block, and the two corner blocks are arranged in a conventional bilateral symmetry manner. Wherein, the width of two sideboard of corner block is different, is wide sideboard and narrow sideboard respectively. The male surface of the wide side plate is welded with the metal plate body in the middle of the shoe base 11, the male surface is perpendicular to the front wall surface of the metal plate body, and reinforcing ribs in a triangular plate shape are uniformly welded in an internal corner cavity formed at the welding position of the male surface and the front wall surface of the metal plate body. In addition, a second hole 02 in a circular through hole shape is formed in the waist part at the front end of the wide-side plate, and the second hole 02 is a threaded hole.

Referring to fig. 6 and 7, the groove body of the boot groove 12 of the present invention has a square groove shape, and the groove opening faces forward. The upper and lower end parts of the wing plates at the left and right sides of the boot groove 12 are respectively provided with a third hole 03 in a circular through hole shape, and the third hole 03 is a threaded hole. Wherein, two holes III 03 on the same wing plate are arranged up and down symmetrically. The middle parts of the wing plates at the left side and the right side of the boot groove 12 are respectively provided with a hole four 04 in a circular through hole shape. The upper end and the lower end of the web of the boot groove 12 are respectively provided with a hole five 05 in a circular through hole shape, the two holes five 05 are arranged in a vertical symmetry manner, and the two holes five 05 can be respectively aligned with the two holes one 01 on the boot base 11.

Referring to fig. 8, the guide wheel 13 of the present invention includes a wheel body 1301 having a circular ring shape, a first bearing 1302 installed in a circular cavity of the wheel body 1301, and a positioning cylinder 1303 installed in a shaft hole of the first bearing 1302. The outer ring of the first bearing 1302 is fixedly connected with the cavity wall of the annular cavity of the wheel body 1301, and the inner ring of the first bearing 1302 is fixedly sleeved on the cylinder body of the positioning cylinder 1303.

The cylinder body of the positioning cylinder 1303 is in a shape of a round straight rod, and the middle part of the cylinder body of the positioning cylinder 1303 is provided with a hole six 06 in a shape of a round through hole. And three grooves are formed in the cavity wall of the hole cavity of the hole six 06, the three grooves are distributed in a circumferential array shape, and the hole six 06 can be aligned with the hole four 04.

The thread of the third screw 003 is close to the countersunk head of the third screw 003, the part of the third screw 003, which is far away from the countersunk head, is a round straight rod, and the round straight rod is uniformly connected with raised lines which are used for being spliced in grooves formed in the sixth hole 06. The diameter of the screw III 003 at the convex strip is smaller than that of the threaded part of the screw 003, so that the convex strip of the screw III 003 can pass through the hole cavity of the hole II 02.

Referring to fig. 9 and 10, the boot liner 14 of the present invention is a square groove shaped groove body that can be inserted into the groove of the boot groove 12, with the groove opening facing forward. The upper and lower end portions of the wing plates on the left and right sides of the shoe lining 14 are respectively provided with a hole seven 07 in the shape of a round blind hole, and the hole seven 07 can be aligned with the hole three 03. The web of the liner 14 defines two holes eight 08 with stepped through holes, the two holes eight 08 are arranged symmetrically up and down, and the two holes eight 08 can be respectively aligned with the two holes five 05 on the boot groove 12. In addition, the inner wall surface of the web plate of the shoe liner 14 is also evenly provided with anti-skid grains.

Referring to fig. 11, the present invention provides a mold 2 including a first mold 21 for receiving the elevator shoe 1 and a second mold 22 for lifting a second screw 002.

Referring to fig. 12, a first module 21 of the present invention includes a base 100, a rotatable base 200, a pad 300, and a screw 004.

Referring to fig. 13, the base 100 of the present invention includes a base body 110 in a circular cake shape and a second bearing 120. The middle part of the base seat body 110 is provided with a hole nine 101 in a round blind hole shape, the second bearing 120 is arranged in a hole cavity of the hole nine 101, and an outer ring of the second bearing 120 is fixedly connected with the wall of the hole cavity of the hole nine 101.

Referring to fig. 14 and 15, the swivel mount 200 of the present invention includes a swivel mount body 210 in a square plate shape, a first swivel mount stand 220 in a T-shape welded to a top wall of a middle portion of the swivel mount body 210, two swivel hinge eyes 230 symmetrically arranged in a left-right direction, a second swivel mount stand 240 in a square plate shape welded to a top wall of a front portion of the swivel mount body 210, and a rotating shaft 250 in a cylindrical shape welded to a bottom wall of a middle portion of the swivel mount body 210.

Wherein, set up two dead slots 201 that are bilateral symmetry and set up on the block of swivel mount founding platform one 220, the roof at the both ends is seted up three and is used four 004 holes ten 202 that are circular blind hole form of installing screw about swivel mount founding platform one 220 to hole ten 202 is the screw hole. Two empty slots 201 separate the block of swivel mount stand one 220 into a left block, a middle block and a right block, and two swivel mount hinge lugs 230 are welded respectively at the front wall of the waist of the middle block. Each swivel hinge lug 230 is provided with an eleven circular through hole 203, and the eleven circular through hole 203 is a threaded hole. Two sliding grooves 204 which are arranged in a bilateral symmetry mode are formed in the block body of the second rotating base stand platform 240, the block body of the second rotating base stand platform 240 is divided into a left block body, a middle block body and a right block body through the two sliding grooves 204, two first opening grooves 205 which are symmetrical up and down are formed in the front wall of the middle block body, and a groove cavity of the first opening groove 205 is a spherical surface. In addition, the left and right side cavity walls of the cavity of the sliding groove 204 are provided with a square column-shaped bar for guiding. The shaft body of the rotating shaft 250 is inserted into the shaft hole of the second bearing 120, and the shaft body of the rotating shaft 250 is fixedly connected with the inner ring of the second bearing 120.

Referring to fig. 16 and 17, the cushion 300 of the present invention includes a block-shaped cushion body 310, an L-shaped cushion stopper 320, and a block-shaped cushion ear block 330. Wherein, the cushion stopper 320 is welded at the left end of the cushion body 310, and the cushion ear block 330 is welded at the right end of the cushion body 310. In addition, two holes twelve 301 with stepped through holes are formed in the block body of the shoe base body 310, and the two holes twelve 301 can be respectively aligned with the two holes eight 08 on the shoe liner 14. Both the shoe stop 320 and the shoe ear block 330 define a thirteen hole 302 that is capable of aligning with the thirteen hole 202.

Referring to fig. 18, the second module 22 of the present invention includes a push rod 400, two hinge mounts 500, two hinge cylinders 600, two hinge brackets 700, two top piles 800, two screws five 005, two screws six 006, and two screws seven 007. Wherein, every six 006 screws are all furnished with the nut of an adaptation.

Referring to fig. 19 and 20, the push rod 400 according to the present invention includes a rod body 410, a spring 420, a ball 430, and a block-shaped pulling cover 440.

The front walls of the left end and the right end of the handspike body 410 are respectively provided with a fourteen hole 401 which is a step-shaped blind hole, and the two fourteen holes 401 are arranged in a left-right symmetrical manner. The rear walls of the left end and the right end of the putter body 410 are respectively provided with a square blind hole-shaped fifteen 402, the two holes fifteen 402 are symmetrically arranged left and right, and the cavities of the two holes fifteen 402 are respectively communicated with the cavities of the two holes fourteen 401 on the putter body 410.

The rear wall in the middle of the push rod body 410 is provided with a sixteen hole 403 in a square blind hole shape, and the middle of the front wall of the hole cavity of the sixteen hole 403 is provided with a seventeen hole 404 in a round blind hole shape. Both the spring 420 and the ball 430 are disposed in the bore of the hole seventeen 404, and the ball 430 is located behind the spring 420. In addition, the insert 440 snaps into the bore of the hole sixteen 403 to restrain the ball 430 and prevent the ball 430 from fully ejecting out of the bore of the hole seventeen.

The left and right sides of the embedding cover 440 are respectively provided with a notch 405 so as to lift the embedding cover 440 out of the cavity of the sixteen holes 403. The middle part of the embedding cover 440 is provided with a hole eighteen 406 in a circular through hole shape, and part of the ball body of the ball 430 can be exposed from the hole eighteen 406.

Referring to fig. 21 and 22, the front end of the hinge base 500 provided by the present invention is inserted into the hole cavity of the fifteen 402, and the front wall of the hinge base 500 is opened with a nineteen 501 in the form of a round blind hole capable of aligning with the fourteen 401, and the nineteen 501 is a screw hole. The left side and the right side of the waist of the hinged support 500 are both provided with a second notch 502, the waist of the hinged support 500 is inserted into the groove cavity of the sliding groove 204, and the notches 502 are sleeved on the column bars arranged on the left side wall and the right side wall of the groove cavity of the sliding groove 204 and move up and down along the column bars. The rear end of the hinged support 500 is provided with a third notch 503, and the cavity walls on the left side and the right side of the third notch 503 are respectively provided with twenty round through hole-shaped holes 504. Screw five 005 is inserted through hole fourteen 401 and threaded into the bore of hole nineteen 501.

Referring to fig. 23 and 24, the hinge pin 600 of the present invention includes a hinge pin body 610 having a shape of a circular straight tube and a hinge pin ear piece 620 welded to the front end of the hinge pin body 610 for inserting into the three-503 slotted-slot cavity. The barrel hinge lug 620 is provided with a twenty-one 601 aligned with the twenty-504 hole, and the nut is screwed after the screw six 006 passes through the twenty-504 hole and the twenty-one 601 hole, so that the barrel hinge 600 is hinged with the hinge base 500.

Referring to fig. 25, a hinge frame 700 according to the present invention includes a first hinge frame body 710 and a second hinge frame body 720. One end of the first hinge frame body 710 is a circular ring body, the ring cavity of the circular ring body and the eleven holes 203, the other end of the first hinge frame body 710 is two runway-shaped ring bodies which are symmetrically arranged, and the runway-shaped ring bodies are provided with gaps. The second hinge frame body 720 is a circular straight rod, one end of the second hinge frame body 720 is welded on the circular ring body, and the second hinge frame body 720 is movably inserted in the barrel cavity of the hinge barrel body 610.

Referring to fig. 26, the pile 800 of the present invention includes a hinge 810 for hinge-connecting with the race-track-shaped ring body and a top rod 820 for pushing the screw two 002 upward. Hinge rods 810 snap into the race track ring body cavity at the notches in the race track ring body. The top bar 820 is in a shape of a round straight bar, and the top end of the top bar 820 is in a hexagonal prism.

Example two

Referring to fig. 28-32, the present invention provides a method for processing an elevator guide shoe 1 by a special elevator component equipment mold.

S1, first, the pushing rod body 410 is pushed upward by hand, so that the pushing rod 400 is pushed to the front of the first notch 205 located above in the second rotating stand 240. At this time, the hole eighteen 406 is aligned with the first notch 205, the ball 430 is no longer blocked by the rotating stand 240, the compressed spring 420 is restored by its own elasticity and pushes the ball 430 backwards, so that the ball body at the rear of the ball 430 is clamped into the inner cavity of the first notch 205, and the push rod 400 is limited right in front of the first notch 205.

In the present invention, during the period of pushing the push rod body 410 upwards, under the driving action of the push rod 400, the hinge base 500 slides upwards along the sliding groove 204, so that the hinge barrel 600 moves upwards, and the hinge barrel 600 tilts under the limitation of the hinge frame body two 720, and drives the hinge frame body two 720 to rotate around the screw seven 007, so that the hinge frame body one 710 rotates around the screw seven 007, and the top pile 800 is pulled downwards through the hinge frame body one 710, so that the top of the top rod 820 is pulled into the bottom cavity of the hole twelve 301.

Then, two screws two 002 are picked up, the two screws two 002 are inserted into the cavities of the two holes twelve 301 from the upper orifices of the two holes twelve 301 in the shoe base body 310 with the countersunk heads facing downward, and the screws two 002 are turned by hand, so that the inner hexagonal grooves at the countersunk heads of the screws two 002 are aligned with the top of the push rod 820. Thus, the second screw 002 can be completely placed into the cavity of the second hole 301, and the hexagonal prism-shaped rod body of the top rod 820 is inserted into the inner hexagonal groove at the countersunk position of the second screw 002.

Finally, a shoe 14 is picked up, the slot of the shoe 14 is clamped down on the block of the shoe base body 310, and the shoe 14 is moved to the left to bring the shoe 14 and the shoe base stopper 320 into abutment. At this time, the two holes eight 08 of the bootie 14 are aligned with the two holes twelve 301 of the shoe pad body 310, respectively.

S2, first, pick up a boot groove 12, snap the notch of the boot groove 12 down onto the bootie 14 in S1, and move the boot groove 12 to the left to bring the boot groove 12 into abutment with the shoe block 320. At this point, the two holes five 05 on the boot groove 12 are aligned with the two holes eight 08 on the bootie 14, respectively, and the four holes three 03 on the boot groove 12 are aligned with the four holes seven 07 on the bootie 14, respectively.

Then, the four screws one 001 are picked up, and the four screws one 001 are screwed into the holes three 03 respectively and tightened. At this time, the non-countersunk end of the screw one 001 is inserted into the bore of the hole seven 07, so that the shoe lining 14 is fixed within the groove cavity of the shoe groove 12.

S3, first, the rod body 410 is pushed downward by hand, and the push rod 400 is pushed to the front of the first notch 205 located below in the second rotary stand 240. At this time, the hole eighteen 406 is aligned with the first notch 205, the ball 430 is no longer blocked by the rotating stand 240, the compressed spring 420 is restored by its own elasticity and pushes the ball 430 backwards, so that the ball body at the rear of the ball 430 is clamped into the inner cavity of the first notch 205, and the push rod 400 is limited right in front of the first notch 205.

In the present invention, during the downward pushing of the putter body 410, the rear ball of the ball 430 is first pressed into the hole of the hole eighteen 406 until the hole eighteen 406 is aligned with the first notch 205, and then the ball at the rear of the ball 430 will enter the inner cavity of the first notch 205 under the pushing of the spring 420. Under the driving effect of push rod 400, free bearing 500 slides down along spout 204, and then makes hinge section of thick bamboo 600 downstream, and hinge section of thick bamboo 600 inclines under the restriction of hinge frame body two 720, and drives hinge frame body two 720 and rotates around screw seven 007, thereby make hinge frame body one 710 rotate around screw seven 007, and then promote the fore-set pile 800 upwards through hinge frame body one 710, make ejector pin 820 along the upwards motion of hole twelve 301, and make the non-countersunk head end of screw two 002 pass hole eight 08 and hole five 05 in proper order.

Then, one shoe 11 is pushed and picked up downward, the front wall of the metal plate body in the middle of the shoe 11 is adjusted to face downward, and the two L-shaped corner blocks of the shoe 11 are adjusted to be in tandem.

Finally, the two holes one 01 of the adjusted shoe 11 are respectively aligned and sleeved on the non-countersunk ends of the two screws two 002 jacked by the jacking pile 800, nuts are screwed on and tightened, and the shoe lining 14, the boot groove 12 and the shoe 11 are fixedly installed together. At this point, hole two 02 is aligned with hole four 04.

S4, first, pick up two guide wheels 13, place them in the two clamping cavities formed by the shoe 11 and the boot groove 12, respectively, and align the hole six 06 with the hole two 02.

Then, two screws three 003 are picked up, the two screws three 003 are respectively aligned with the holes six 06 of the two guide wheels 13, and the screws three 003 are screwed into the holes two 02 and tightened. At this point, the non-countersunk end of screw three 003 passes through hole six 06 and is inserted into the bore of hole four 04. In this way, the assembling work of the elevator guide shoe 1 is completed, and the assembled elevator guide shoe 1 can be directly removed from the mold 2.

In the foregoing, exemplary embodiments of the proposed solution of the present invention have been described in detail with reference to preferred embodiments, however, it will be understood by those skilled in the art that various changes and modifications may be made to the specific embodiments described above, and various combinations of the various technical features and structures proposed by the present invention may be made without departing from the concept of the present invention, and the scope of the present invention is determined by the appended claims.

Claims (11)

1. The utility model provides an equipment mould of special type elevator spare part, leads boots (1) including the elevator, its characterized in that: the elevator guide shoe assembly is characterized by also comprising a die (2) for assembling the elevator guide shoe (1);

the elevator guide shoe (1) comprises a shoe base (11), a shoe groove (12), a guide wheel (13) and a shoe lining (14), and the elevator guide shoe (1) further comprises a first screw (001) limiting the shoe lining (14) inside the shoe groove (12), a second screw (002) installing the shoe groove (12) and the shoe lining (14) in front of the shoe base (11) and a third screw (003) installing the guide wheel (13) in a clamping cavity formed between the shoe base (11) and the shoe groove (12);

the mould (2) comprises a first mould set (21) and a second mould set (22);

the first module (21) comprises a base (100) which is stably placed on a table top, a rotary seat (200) which can rotate on the base (100) and is used for installing a second module (22), and a cushion seat (300) which is used for placing an elevator guide shoe (1), and the first module (21) further comprises a screw four (004) which is used for fixing the cushion seat (300) on the top of the rotary seat (200);

the second module (22) comprises a push rod (400) which is manually pushed to move up and down, a hinged support (500) which moves up and down along with the push rod (400), a hinged cylinder (600) hinged to the hinged support (500), a hinged frame (700) driven by the hinged cylinder (600) and a top pile (800) driven by the hinged frame (700), and the second module (22) further comprises a fifth screw (005) which fixes the push rod (400) at the front part of the hinged support (500), a sixth screw (006) which hinges the hinged support (500) and the hinged cylinder (600) and a seventh screw (007) which installs the hinged frame (700) on the hinged support (200).

2. The equipment mold for special elevator components and parts according to claim 1, wherein: a first hole (01) for mounting a second screw (002) and a second hole (02) for mounting a third screw (003) are formed in the shoe base (11);

a hole III (03) for mounting a screw I (001), a hole IV (04) which can be aligned with the hole II (02) and is used for mounting a screw III (003) and a hole V (05) which can be aligned with the hole I (01) and is used for mounting a screw II (002) are formed in the boot groove (12);

the guide wheel (13) comprises a wheel body (1301), a bearing I (1302) installed in an inner cavity of the wheel body (1301) and a positioning cylinder (1303) installed in a shaft hole of the bearing I (1302), wherein the middle part of the positioning cylinder (1303) is provided with a hole six (06) which can be aligned with the hole two (02) and the hole four (04) and is used for installing a screw three (003);

the shoe lining (14) is provided with a hole seven (07) which can be aligned with the hole three (03) and is used for mounting a screw I (001) and a hole eight (08) which can be aligned with the hole five (05) and is used for mounting a screw II (002).

3. The equipment mold for special elevator components and parts according to claim 2, wherein: the base (100) comprises a base body (110) and a second bearing (120), wherein a hole (101) for mounting the second bearing (120) is formed in the middle of the base body (110).

4. The equipment mold for special elevator components according to claim 3, wherein: the swivel base (200) comprises a swivel base body (210), a swivel stand first (220) welded on the top wall of the middle part of the swivel base body (210), a swivel hinge lug (230) welded on the front wall of the middle part of the swivel stand first (220), a swivel stand second (240) welded on the top wall of the front part of the swivel base body (210) and a rotating shaft (250) welded on the bottom wall of the middle part of the swivel base body (210);

the utility model discloses a bearing structure of a push rod (400) is characterized in that swivel mount pedestal (210) is arranged in directly over base pedestal (110), set up two dead slots (201) that are used for placing fore-set (800) on swivel mount stand (220), the top of swivel mount stand (220) is still evenly seted up and is used for installing ten (202) in the hole that screw four (004), set up on swivel mount hinge lug (230) and be used for installing the hole eleven (203) of screw seven (007), set up two spout (204) that are used for placing hinge seat (500) and two and be used for carrying out spacing groove one (205) to push rod (400) on swivel mount stand two (240), pivot (250) are installed in the shaft hole of bearing two (120).

5. The equipment mold for special elevator components according to claim 4, wherein: the cushion seat (300) comprises a cushion seat body (310), a cushion seat stop block (320) welded at the left end of the cushion seat body (310) and a cushion seat ear block (330) welded at the right end of the cushion seat body (310);

the cushion seat (300) is installed at the top of a first rotating seat stand (220), two holes twelve (301) which are aligned with two empty grooves (201) on the first rotating seat stand (220) are formed in the cushion seat base body (310), the holes twelve (301) are aligned with eight (08) holes, and a cushion seat stop block (320) and a cushion seat ear block (330) are provided with thirteen holes (302) which are aligned with ten holes (202) and used for installing four (004) screws.

6. The equipment mold for special elevator components and parts according to claim 5, wherein: the push rod (400) comprises a push rod body (410) pushed by a hand, and a spring (420), a ball (430) and a cover (440) which are arranged inside the push rod body (410);

the front walls of the left end and the right end of the push rod body (410) are provided with fourteen holes (401), the rear walls of the left end and the right end of the push rod body (410) are provided with fifteen holes (402) communicated with the fourteen holes (401) and used for inserting the front end part of the hinged support (500), and the rear wall of the middle part of the push rod body (410) is provided with sixteen holes (403) used for installing the embedded cover (440) and seventeen holes (404) communicated with the sixteen holes (403) and used for installing the spring (420) and the ball (430);

the spring (420) is located in front of the ball (430), the left side and the right side of the embedding cover (440) are provided with notches (405), and the middle of the embedding cover (440) is provided with a hole eighteen (406).

7. The equipment mold for special elevator components and parts according to claim 6, wherein: the hinge base (500) is provided with a nineteen hole (501) which can be aligned with the fourteen hole (401) and is used for mounting a screw five (005), a second notch (502) which can move up and down along the sliding groove (204), a third notch (503) which is used for mounting the hinge barrel (600) and a twenty hole (504) which is used for mounting a screw six (006).

8. The equipment mold for special elevator components according to claim 7, wherein: the hinge cylinder (600) comprises a hinge cylinder body (610) and a hinge cylinder ear block (620) welded at the front end of the hinge cylinder body (610) and used for being inserted into the notch III (503), and a hole twenty-one (601) which can be aligned with the hole twenty (504) and used for mounting the screw six (006) is formed in the hinge cylinder ear block (620).

9. The equipment mold for special elevator components according to claim 8, wherein: the hinge bracket (700) comprises a hinge bracket body I (710) used for driving the jacking pile (800) and a hinge bracket body II (720) driven by the hinge cylinder body (610);

one end of the first hinge frame body (710) is a circular ring body, the other end of the first hinge frame body (710) is a runway ring body, a ring cavity of the circular ring body of the first hinge frame body (710) is aligned with the first hole (203) and used for mounting a screw seven (007), one end of the second hinge frame body (720) is welded on the circular ring body of the first hinge frame body (710), and the other end of the second hinge frame body (720) is inserted into a barrel cavity of the hinge barrel body (610).

10. The equipment mold for special elevator components according to claim 9, wherein: the top pile (800) comprises a hinge rod (810) hinged with the runway-shaped ring body of the first hinge frame body (710) and a top rod (820) welded in the middle of the hinge rod (810) and inserted into the hole cavity of the twelve holes (301);

the axis of the top rod (820) is perpendicular to the axis of the hinge rod (810), and the top end of the top rod (820) is hexagonal prism-shaped.

11. The method for processing the elevator guide shoe (1) by the equipment die of the special elevator part according to claim 10 is characterized by comprising the following specific steps:

s1, mounting a screw II (002) in the hole cavity of the hole twelve (301), and mounting the shoe lining (14) on the shoe base body (310);

s2, assembling the boot groove (12) and the boot liner (14) together by using a first screw (001) to form a first assembly;

s3, assembling the shoe base (11) and the assembly formed in the S2 together by using a second screw (002) and a nut matched with the second screw to form a second assembly;

s4, assembling the guide wheel (13) and the assembly formed in the S3 together by using a screw III (003) to form the elevator guide shoe (1).

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