CN116213815B

CN116213815B - On-ice mapping foot rest processing and manufacturing device

Info

Publication number: CN116213815B
Application number: CN202211705242.1A
Authority: CN
Inventors: 孙良宇; 王明亮; 岳昊; 陈大勇; 辛全; 关辅兴; 郭玉峰
Original assignee: Second Geodetic Survey Team Of Ministry Of Natural Resources (heilongjiang First Surveying And Mapping Engineering Institute)
Current assignee: Second Geodetic Survey Team Of Ministry Of Natural Resources (heilongjiang First Surveying And Mapping Engineering Institute)
Priority date: 2022-12-29
Filing date: 2022-12-29
Publication date: 2023-11-21
Anticipated expiration: 2042-12-29
Also published as: CN116213815A

Abstract

The utility model provides an on-ice survey and drawing foot rest processing manufacturing installation, includes frame, taper sleeve, differential pole, cutting device, and cutting device includes slide, drive seat, blade holder, have the V-arrangement seat in the middle of the frame rear side, V-arrangement seat upper portion has a plurality of bolts, have the medium plate in the middle of the frame, have the centre bore in the middle of the medium plate, the centre bore right side has the differential pole hole, differential pole hole lower part has the motor board, differential pole hole front side has the spout, the spout front side has the back board, the front internal screw thread has in the middle of the back board, front internal screw thread and differential pole hole coaxial line, the taper sleeve outside has the link, the link rear side has perforation and taper sleeve coaxial line, the perforation right side has back internal screw thread, back internal screw thread lower part has the slider, slider sliding connection spout, the taper sleeve slides in the spout.

Description

On-ice mapping foot rest processing and manufacturing device

Technical Field

The invention relates to the field of mapping foot frames, in particular to a device for processing and manufacturing an on-ice mapping foot frame.

Background

Many pipe fittings are used to survey and drawing foot rest shank on ice, and the pipe fitting adopts thin wall pipe fitting processing as far as possible, and the survey and drawing is portable, and the cutting of thin wall pipe fitting warp easily, has influenced intensity and the precision of survey and drawing foot rest processing preparation on ice, needs a pipe fitting cutting device to solve the problem that survey and drawing foot rest pipe fitting cutting warp on ice.

Disclosure of Invention

The invention provides the processing and manufacturing device for the on-ice mapping foot rest, which aims at the defects in the prior art and is high in deformation prevention and cutting efficiency.

The invention aims at realizing the following technical scheme:

The differential rod is provided with front threads, rear threads are arranged on the rear sides of the front threads, gears are arranged on the rear sides of the rear threads, the rear sides of the differential rod are slidingly connected with the differential rod holes, the differential rod slides in the differential rod holes, the front threads are rotationally connected with front internal threads, the rear threads are rotationally connected with rear internal threads, the upper part of a motor plate is fixedly connected with a motor, the output shaft of the motor is fixedly connected with a motor gear, and the motor gear and the gears are mutually meshed.

The middle of the sliding seat is provided with a sliding seat hole, the rear side of the sliding seat is provided with a step, the end face of the step is uniformly distributed with four sliding grooves, the rear side of the sliding seat is provided with a shaft collar, the rear side of the shaft collar is provided with a sliding seat gear, the middle of the driving seat is provided with a driving seat hole, the end face of the driving seat is uniformly distributed with four driving seat holes, the rear side of the driving seat is provided with a flange, the flange is internally rotationally connected with the step, and the driving seat rotates around the step.

The beneficial effects are that:

the invention can automatically complete the cutting of the pipe fitting, the deformation is avoided in the cutting process, the cutting efficiency is high, the invention avoids the stress deformation of the pipe fitting from three aspects, firstly, four tool bits simultaneously cut, the pipe fitting is stressed in four directions, the stress is balanced, the pipe fitting cannot be bent due to unbalanced stress, secondly, the four tools simultaneously cut, the cutting force is dispersed, the pipe fitting cannot deform due to local stress, thirdly, the four tool bits gradually cut in the cutting process, the cutting force is small, the pipe fitting stress is further avoided, the deformation of the pipe fitting is reduced, the differential rod plays a role of controlling the feeding amount, the differential rod is provided with a front thread and a rear thread, the front thread and the rear thread are provided with different pitches, the differential rod moves forwards under the driving of the front internal thread and the rear thread simultaneously, the forward moving amount of the taper sleeve relative to the frame is equal to the pitch difference of the front thread and the rear thread, the differential rod rotates one circle, the forward moving distance of the taper sleeve is fixed, the feeding amount of the four tool bits is effectively controlled, the taper sleeve is enabled to be controlled by one circle when the taper sleeve is rotated, the cutting force is controlled by one circle, the position of the cut angle is more accurately controlled, the mapping is carried by the measuring position is more accurately, the measuring and mapping is carried on the pipe fitting is more accurately, and the measuring position is more controlled.

Drawings

Fig. 1 is a schematic structural diagram of a processing and manufacturing device for an on-ice mapping foot rest.

Fig. 2 is a schematic diagram of the rear side structure of the on-ice mapping foot rest processing and manufacturing device according to the invention.

Fig. 3 is a schematic view of a frame structure according to the present invention.

Fig. 4 is a schematic view of the taper sleeve according to the present invention.

Fig. 5 is a schematic view of a differential lever structure according to the present invention.

Fig. 6 is a schematic structural view of a cutting device according to the present invention.

Fig. 7 is a schematic front view of a cutting device according to the present invention.

Fig. 8 is a schematic view of the internal structure of the cutting device according to the present invention.

Fig. 9 is a schematic cross-sectional view of a slide according to the present invention.

Fig. 10 is a schematic cross-sectional view of a driving seat according to the present invention.

Fig. 11 is a schematic view of a rear side structure of a driving seat according to the present invention.

Fig. 12 is a schematic view of a tool holder according to the present invention.

Fig. 13 is a schematic cross-sectional view of a tool holder according to the present invention.

Detailed Description

The invention is described in further detail below with reference to the drawings and examples:

the device comprises a frame 110, a taper sleeve 120, a differential rod 130 and a cutting device 200, wherein the cutting device 200 comprises a sliding seat 210, a driving seat 220 and a tool apron 230, a V-shaped seat 111 is arranged in the middle of the rear side of the frame 110, a plurality of bolts 112 are arranged at the upper part of the V-shaped seat 111, a middle plate 113 is arranged in the middle of the frame 110, a central hole 114 is arranged in the middle of the middle plate 113, a differential rod hole 115 is arranged on the right side of the central hole 114, a motor plate 116 is arranged at the lower part of the differential rod hole 115, a sliding groove 117 is arranged at the front side of the differential rod hole 115, a rear plate 118 is arranged at the front side of the sliding groove 117, a front internal thread 119 is arranged in the middle of the rear plate 118, the front internal thread 119 and the differential rod hole 115 are coaxial, a connecting frame 121 is arranged at the outer side of the taper sleeve 120, a through hole 122 and the taper sleeve 120 are coaxial, a rear internal thread 123 is arranged at the right side of the through hole 122, a sliding block 124 is arranged at the lower part of the rear internal thread 123, the sliding block 124 is connected with the sliding groove 117 in a sliding way, and the taper sleeve 120 slides in the sliding groove 117.

The front side of the differential rod 130 is provided with a front thread 131, the rear side of the front thread 131 is provided with a rear thread 132, the rear side of the rear thread 132 is provided with a gear 133, the rear side of the differential rod 130 is slidingly connected with the differential rod hole 115, the differential rod 130 slides in the differential rod hole 115, the front thread 131 is rotationally connected with a front internal thread 119, the rear thread 132 is rotationally connected with a rear internal thread 123, the upper part of the motor plate 116 is fixedly connected with a motor 150, the output shaft of the motor 150 is fixedly connected with a motor gear 140, and the motor gear 140 and the gear 133 are meshed with each other.

The middle of the sliding seat 210 is provided with a sliding seat hole 211, the rear side of the sliding seat 210 is provided with a step 212, the end face of the step 212 is uniformly distributed with four sliding grooves 213, the rear side of the sliding seat 210 is provided with a collar 214, the rear side of the collar 214 is provided with a sliding seat gear 215, the middle of the driving seat 220 is provided with a driving seat hole 221, the end face of the driving seat 220 is uniformly distributed with four driving seat holes 221, the rear side of the driving seat 220 is provided with a flange 223, the flange 223 is rotationally connected with the step 212, and the driving seat 220 rotates around the step 212.

The upper part of the tool holder 230 is provided with a tool holder shaft 231, the upper part of the tool holder shaft 231 is provided with a conical block 232, the bottom of the conical block 232 is provided with a tool hole 233, the upper part of the tool hole 233 is provided with a counter bore 234 in the vertical direction, each chute 213 is internally connected with the tool holder 230 in a sliding way, each tool holder 230 slides in the chute 213, each chute 213 is internally provided with a spring 260, the inner side of the spring 260 props against the inner side of the chute 213, the outer side of the spring 260 props against the inner side of the tool holder 230, each tool holder shaft 231 is simultaneously connected with an arc-shaped groove 222 in a sliding way, each tool holder 230 simultaneously slides in the arc-shaped groove 222, each counter bore 234 is internally connected with a fastening bolt 250 in a threaded way, each tool bit 240 is arranged in each tool bit 233, the rear side of the tool bit 240 is flush with the rear side of the tool bit 233, and the tool bit 240 are fixedly connected with the tool holder 230 through the fastening bolt 250.

The slide gear 215 is rotatably connected with the central hole 114, the slide 210 rotates in the central hole 114, the slide gear 215 and the gear 133 are meshed with each other, and four tool holders 230 are arranged on the inner side of the taper sleeve 120.

In the present invention, the pipe 170 is placed on the V-shaped seat 111, the front side of the pipe 170 passes through the taper sleeve 120, the driving seat hole 221, the sliding seat hole 211 and the through hole 122, the V-shaped cover 160 is sleeved into the bolt 112, the pipe 170 is clamped between the V-shaped cover 160 and the V-shaped seat 111 by the nut, the motor 150 is started, the motor 150 rotates to drive the motor gear 140 to rotate, the motor gear 140 rotates to drive the gear 133 to rotate, the gear 133 rotates to drive the sliding gear 215 to rotate, the sliding gear 215 rotates, the whole cutting device 200 rotates, the four tool holders 230 drive the four tool bits 240 to rotate simultaneously, the front thread 131 rotates in the front internal thread 119, the rear thread 132 rotates in the rear internal thread 123, the differential rod 130 moves forward, the taper sleeve 120 slides forward, the four tool holders 230 inside the taper sleeve 120 move inward simultaneously under the drive of the taper sleeve 120, the tool holders 230 move inward inwards, the tool holders 240 move inward along with the tool holders 230, the front side of the tool holders 240 gradually contacts with the pipe 170 and cuts into the pipe 170, the motor 215 is cut off, the motor 215 is stopped to cut off, the rear thread 150 rotates in the rear thread 150, the four tool holders 170 rotate in the reverse direction, and the reset spring 260 moves down, and the four tool holders 170 rotate in the reverse direction, and the lower thread is reset to the side of the tool holder 150, and the lower the tool holder 150 rotates.

The invention can automatically complete the cutting of the pipe fitting, the deformation is avoided in the cutting process, the cutting efficiency is high, the invention avoids the stress deformation of the pipe fitting 170 from three aspects, firstly, four cutter heads 240 simultaneously cut, the pipe fitting 170 is stressed in four directions, the stress is balanced, the pipe fitting 170 cannot be bent due to unbalanced stress, secondly, four cutters simultaneously cut, the cutting force is dispersed, the pipe fitting 170 cannot be deformed due to local stress, thirdly, four cutter heads 240 gradually cut in the cutting process, the cutting force is small, the excessive stress of the pipe fitting 170 is further avoided, the deformation of the pipe fitting 170 is reduced, the differential rod 130 plays a role of controlling the feeding amount, the differential rod 130 is provided with a front thread 131 and a rear thread 132, the front thread 131 and the rear thread 132 have different pitches, the differential rod 130 simultaneously drives the rear internal thread 123 under the driving of the front internal thread 119, the taper sleeve 120 simultaneously moves backwards under the driving of the front thread 131, the forward moving amount of the taper sleeve 120 relative to the frame 110 is equal to the pitch difference of the front thread 131 and the rear thread 132, the differential rod 130 rotates for each circle, the differential rod 130 moves forward by one circle, the cutter head 120 is effectively controlled by a certain distance, and the cutting amount of the pipe fitting 170 is reduced when the cutting force is controlled for each circle 170 is effectively controlled, and the deformation of the pipe fitting 170 is reduced when the cutting is controlled. The support position is more accurate, and the survey and drawing foot rest weight on ice of preparation is lighter, portable has improved survey and drawing accuracy.

An operation method of an on-ice mapping foot rest processing and manufacturing device comprises the following steps: the first step is to place the pipe 170 on the upper part of the V-shaped seat 111, the front side of the pipe 170 passes through the taper sleeve 120, the driving seat hole 221, the sliding seat hole 211, the through hole 122, the V-shaped cover 160 is sleeved into the bolt 112, the pipe 170 is clamped between the V-shaped cover 160 and the V-shaped seat 111 by the nut, and the second step is to start the motor 150, so that the cutting work is automatically completed.

Claims

1. The device is characterized by comprising a frame, a taper sleeve, a differential rod and a cutting device, wherein the cutting device comprises a sliding seat, a driving seat and a cutter seat, a V-shaped seat is arranged in the middle of the rear side of the frame, a plurality of bolts are arranged on the upper part of the V-shaped seat, a middle plate is arranged in the middle of the frame, a central hole is arranged in the middle of the middle plate, a differential rod hole is arranged on the right side of the central hole, a motor plate is arranged at the lower part of the differential rod hole, a sliding chute is arranged at the front side of the differential rod hole, a rear plate is arranged at the front side of the sliding chute, a front internal thread is arranged in the middle of the rear plate, the front internal thread and the differential rod hole are coaxial, a connecting frame is arranged at the outer side of the taper sleeve, a through hole is coaxial with the taper sleeve, a rear internal thread is arranged on the right side of the through hole, a sliding block is arranged at the lower part of the rear internal thread, the sliding block is connected with the sliding chute in a sliding manner, and the taper sleeve slides in the sliding chute; the front side of the differential rod is provided with a front thread, the rear side of the front thread is provided with a rear thread, the rear side of the rear thread is provided with a gear, the rear side of the differential rod is slidingly connected with a differential rod hole, the differential rod slides in the differential rod hole, the front thread is rotationally connected with a front internal thread, the rear thread is rotationally connected with a rear internal thread, the upper part of a motor plate is fixedly connected with a motor, the output shaft of the motor is fixedly connected with a motor gear, and the motor gear and the gear are mutually meshed; the middle of the sliding seat is provided with a sliding seat hole, the rear side of the sliding seat is provided with a step, the end face of the step is uniformly distributed with four sliding grooves, the rear side of the sliding seat is provided with a shaft collar, the rear side of the shaft collar is provided with a sliding seat gear, the middle of the driving seat is provided with a driving seat hole, the end face of the driving seat is uniformly distributed with four driving seat holes, the rear side of the driving seat is provided with a flange, the flange is rotationally connected with the step, and the driving seat rotates around the step; the slide seat gear is rotationally connected with the central hole, the slide seat rotates in the central hole, the slide seat gear is meshed with the gear, and the four tool holders are arranged on the inner side of the taper sleeve.

2. The device for manufacturing the on-ice mapping foot rest according to claim 1, wherein the upper part of the tool holder is provided with a tool holder shaft, the upper part of the tool holder shaft is provided with a conical block, the bottom of the conical block is provided with a tool bit hole, the upper part of the tool bit hole is provided with a countersunk head hole in the vertical direction, each sliding groove is internally and slidably connected with one tool holder, each tool holder slides in the sliding groove, a spring is placed in each sliding groove, the inner side of the spring is propped against the inner side of the sliding groove, the outer side of the spring is propped against the inner side of the tool holder, each tool holder shaft is simultaneously and slidably connected with an arc-shaped groove, each tool bit is simultaneously and slidably connected in the arc-shaped groove, the rear side of each tool bit is flush with the rear side of the tool bit hole, and the tool bit is fixedly connected with the tool holder through the fastening bolts.