CN112554014A - Linear cutting mechanism moving support for cement road construction - Google Patents

Abstract

The invention discloses a linear cutting mechanism moving support for cement road construction, which comprises a main component mounting base plate. The device is matched with an integral cutting device for cement road construction, can work in a fixed-point distance under the action of mechanical parts to realize fixed-point cutting, drives a piston to compress gas by utilizing a rotating state formed by rotating friction, can switch on current after the compressed gas reaches a fixed value, so that a driving motor in the next mechanism works to cut a section, and has strong control capability.

Description

Linear cutting mechanism moving support for cement road construction

Technical Field

The invention relates to the technical field of cement road construction, in particular to a linear cutting mechanism moving support for cement road construction.

Background

At present, after a cement road is formed, in order to prevent a fracture phenomenon caused by stress, cutting is carried out at a fixed point, but the existing cutting device has poor control capability and great defects.

Disclosure of Invention

The invention aims to provide a linear cutting mechanism moving support for cement road construction, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a linear cutting mechanism motion support for cement road construction comprises a main component mounting substrate, wherein a roller supporting rod is mounted on the side face of the bottom of the main component mounting substrate, a main bolt hole is formed in the upper surface of the main component mounting substrate, a rotating wheel groove structure is arranged on a plate body of the main component mounting substrate, a main first supporting rod is mounted on one side of the bottom surface of the main component mounting substrate and located in the rotating wheel groove structure, a main shaft sleeve is mounted at the bottom of the main first supporting rod, a main first rotating shaft is mounted in the main shaft sleeve through a main bearing, a main rotating wheel is mounted at one end of the main first rotating shaft, a rubber ring is sleeved on the circumferential surface of the main rotating wheel, the horizontal height of the bottom of the rubber ring is lower than the bottom of the roller in the roller supporting rod by 0.2-0.5 mm, and a gear-meshing type rotating direction conversion mechanism is mounted at the other end of the main first, the outer side of the gear-meshing type rotation direction conversion mechanism is connected with the bottom of a main component mounting substrate through a main second support rod, a rotating plate is mounted at the end part of a rotating shaft of the gear-meshing type rotation direction conversion mechanism, a fixed rod is mounted at the edge of the bottom surface of the rotating plate, a rod body of the fixed rod is sleeved in an auxiliary shaft sleeve through a main bearing, a main movable rod is mounted on the side surface of the auxiliary shaft sleeve, a main third support rod is mounted at the bottom of the main component mounting substrate, a main copper hollow shell is mounted at the bottom of the main third support rod, a main binding post is mounted on the outer side of the main copper hollow shell, an internal threaded hole is formed in the center of the top end of the main copper hollow shell, a threaded structure-meshing type binding post distance adjusting mechanism is meshed in the internal threaded hole through a main internal threaded structure, and a main hollow, the auxiliary copper piston plate is arranged inside the main hollow structure, a compressed main spiral spring is arranged on the upper surface of the auxiliary copper piston plate, a pipeline hole communicated with the bottom of the side surface of the main hollow structure and internally provided with a main valve core is arranged on the side surface of the main hollow copper shell, a transverse non-conductive main hollow shell is arranged at the bottom of the main hollow copper shell, an auxiliary hollow structure is arranged inside one end of the main hollow shell, an auxiliary piston plate is arranged at one end inside the auxiliary hollow structure through a hinge, a pipeline hole communicated with the auxiliary hollow structure and internally provided with a main first air check valve is arranged at the center of the other end of the main hollow shell, a pipeline hole communicated with the bottoms of the auxiliary hollow structure and the main hollow structure and internally provided with a main second air check valve is arranged at the center of the other end of the main hollow shell, and the air inlet port of the main first air one-way valve and the air outlet port of the main second air one-way valve face to the auxiliary hollow structure.

Further, the gear-mesh-type rotation direction conversion mechanism includes a hollow housing for the gear-mesh-type rotation direction conversion mechanism, a hollow structure for the gear-mesh-type rotation direction conversion mechanism, a bearing for the gear-mesh-type rotation direction conversion mechanism, a first rotation shaft for the gear-mesh-type rotation direction conversion mechanism, a second rotation shaft for the gear-mesh-type rotation direction conversion mechanism, a first bevel gear for the gear-mesh-type rotation direction conversion mechanism, and a second bevel gear for the gear-mesh-type rotation direction conversion mechanism.

Further, a hollow structure for a gear-mesh-type rotation direction converting mechanism is provided inside the hollow housing for a gear-mesh-type rotation direction converting mechanism, a first rotating shaft for a gear-mesh-type rotation direction converting mechanism and a second rotating shaft for a gear-mesh-type rotation direction converting mechanism are respectively attached to a middle portion of both vertical end faces of the hollow housing for a gear-mesh-type rotation direction converting mechanism through bearings for a gear-mesh-type rotation direction converting mechanism, a first bevel gear for a gear-mesh-type rotation direction converting mechanism and a second bevel gear for a gear-mesh-type rotation direction converting mechanism are respectively attached to one end of the first rotating shaft for a gear-mesh-type rotation direction converting mechanism and the second rotating shaft for a gear-mesh-type rotation direction converting mechanism at positions inside the hollow structure for a gear-mesh-type rotation direction converting mechanism, and the first bevel gear for the gear-mesh-type rotation direction conversion mechanism and the tooth structure of the second bevel gear for the gear-mesh-type rotation direction conversion mechanism are meshed with each other.

Further, the gear-mesh type rotation direction conversion mechanism is mounted on the main second support rod at the center of an outer surface of the hollow housing.

Further, the first rotating shaft for the gear mesh type rotation direction converting mechanism and the second rotating shaft for the gear mesh type rotation direction converting mechanism are fixedly connected to an end portion of the main first rotating shaft and a center of an end face of the rotating plate at one end located outside.

Furthermore, the thread structure meshed type binding post distance adjusting mechanism comprises a non-conductive hollow rod for the thread structure meshed type binding post distance adjusting mechanism, an external thread structure for the thread structure meshed type binding post distance adjusting mechanism, a wire hole for the thread structure meshed type binding post distance adjusting mechanism, a block embedded groove structure for the thread structure meshed type binding post distance adjusting mechanism, a copper block for the thread structure meshed type binding post distance adjusting mechanism and a wire embedded groove structure for the thread structure meshed type binding post distance adjusting mechanism.

Furthermore, the side surface of the non-conductive hollow rod for the thread structure meshed type binding post distance adjusting mechanism is provided with an external thread structure for the thread structure meshed type binding post distance adjusting mechanism, the thread structure meshed wiring terminal distance adjusting mechanism is characterized in that a wire guide hole for the thread structure meshed wiring terminal distance adjusting mechanism is arranged in the center of the inner part of the non-conductive hollow rod for the thread structure meshed wiring terminal distance adjusting mechanism, one end of the wire hole for the thread structure engagement type binding post distance adjusting mechanism is provided with a block body embedding groove structure for the thread structure engagement type binding post distance adjusting mechanism, the inside of the block body embedding groove structure for the thread structure meshing type binding post distance adjusting mechanism is embedded with a copper block for the thread structure meshing type binding post distance adjusting mechanism, and a wire embedding groove structure for the thread structure meshing type binding post distance adjusting mechanism is arranged at the center of one end of the copper block for the thread structure meshing type binding post distance adjusting mechanism.

Furthermore, the thread structure meshed type binding post distance adjusting mechanism is meshed with an internal thread structure inside the main internal thread hole through an external thread structure.

Furthermore, the structure of one end of the copper block for the thread structure meshed type binding post distance adjusting mechanism protrudes outwards relative to one end of the block body embedded groove structure for the thread structure meshed type binding post distance adjusting mechanism.

Compared with the prior art, the invention has the beneficial effects that: the device is matched with an integral cutting device for cement road construction, can work in a fixed-point distance under the action of mechanical parts to realize fixed-point cutting, drives a piston to compress gas by utilizing a rotating state formed by rotating friction, can switch on current after the compressed gas reaches a fixed value, so that a driving motor in the next mechanism works to cut a section, and has strong control capability.

Drawings

FIG. 1 is a schematic view of a full-section structure of a linear cutting mechanism moving support for cement road construction according to the present invention;

FIG. 2 is a schematic structural diagram of a gear-mesh-type rotation direction conversion mechanism in a linear cutting mechanism motion support for cement road construction according to the present invention;

FIG. 3 is a schematic structural diagram of a thread-structured meshed terminal distance adjusting mechanism in a linear cutting mechanism moving support for cement road construction according to the present invention;

in the figure: 1, main part mounting base plate, 2, roller support bar, 3, main bolt hole, 4, rotor groove structure, 5, main first support bar, 6, spindle cover, 7, main first rotation axis, 8, main rotor, 9, rubber ring, 10, main second support bar, 11, gear-meshing rotation direction converting mechanism, 111, hollow housing for gear-meshing rotation direction converting mechanism, 112, hollow structure for gear-meshing rotation direction converting mechanism, 113, bearing for gear-meshing rotation direction converting mechanism, 114, first rotation axis for gear-meshing rotation direction converting mechanism, 115, second rotation axis for gear-meshing rotation direction converting mechanism, 116, first bevel gear for gear-meshing rotation direction converting mechanism, 117, second bevel gear for gear-meshing rotation direction converting mechanism, 12, rotation plate, 13, fixing bar, and the like, 14, an auxiliary shaft sleeve, 15, a main movable rod, 16, a main third support rod, 17, a main copper hollow housing, 18, a main hollow housing, 19, a main hollow structure, 20, an internal thread hole, 21, a thread structure mesh type terminal distance adjusting mechanism, 211, a thread structure mesh type terminal distance adjusting mechanism non-conductive hollow rod, 212, a thread structure mesh type terminal distance adjusting mechanism external thread structure, 213, a thread structure mesh type terminal distance adjusting mechanism lead hole, 214, a thread structure mesh type terminal distance adjusting mechanism block embedding groove structure, 215, a thread structure mesh type terminal distance adjusting mechanism copper block, 216, a thread structure mesh type terminal distance adjusting mechanism lead embedding groove structure, 22, a main coil spring, 23, an auxiliary copper piston plate, 24, a main valve core, 25, a main terminal, a secondary copper piston plate, a secondary valve core, a secondary, 26, primary secondary air check valve, 27, secondary hollow structure, 28, secondary piston plate, 29, primary first air check valve.

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.

Referring to fig. 1, an embodiment of the present invention: the main part mounting structure comprises a main part mounting substrate 1, wherein a roller supporting rod 2 is mounted on the side face of the bottom of the main part mounting substrate 1, a main bolt hole 3 is formed in the upper surface of the main part mounting substrate 1, a rotating wheel groove structure 4 is arranged on a plate body of the main part mounting substrate 1, a main first supporting rod 5 is arranged on one side of the rotating wheel groove structure 4 on the bottom surface of the main part mounting substrate 1, a main shaft sleeve 6 is arranged at the bottom of the main first supporting rod 5, a main first rotating shaft 7 is arranged in the main shaft sleeve 6 through a main bearing, a main rotating wheel 8 is arranged at one end of the main first rotating shaft 7, a rubber ring 9 is sleeved on the circumferential surface of the main rotating wheel 8, the horizontal height of the bottom of the rubber ring 9 is lower than the bottom of a roller in the roller supporting rod 2 by 0.2-0.5 mm, a gear-meshing type rotating direction switching mechanism 11 is arranged at the other end of, the outer side of the gear-meshing type rotation direction conversion mechanism 11 is connected with the bottom of a main component mounting base plate 1 through a main second support rod 10, a rotating plate 12 is mounted at one rotating shaft end part of the gear-meshing type rotation direction conversion mechanism 11, a fixed rod 13 is mounted at the edge of the bottom surface of the rotating plate 12, a rod body of the fixed rod 13 is sleeved in an auxiliary shaft sleeve 14 through a main bearing, a main movable rod 15 is mounted on the side surface of the auxiliary shaft sleeve 14, a main third support rod 16 is mounted at the bottom of the main component mounting base plate 1, a main copper hollow shell 17 is mounted at the bottom of the main third support rod 16, a main binding post 25 is mounted at the outer side of the main copper hollow shell 17, an internal thread hole 20 is arranged at the center of the top end of the main copper hollow shell 17, and the internal thread hole 20 is meshed with a thread structure meshing type binding post distance adjusting mechanism 21 through a, the bottom of internal thread hole 20 is provided with main hollow structure 19, the one pair copper piston plate 23 of internally mounted of main hollow structure 19, the main coil spring 22 of an upper surface mounting compression of vice copper piston plate 23, the side of main copper hollow shell 17 is provided with intercommunication main hollow structure 19 side bottom, and internally mounted has the pipeline hole of main valve core 24, a horizontal non-conductor main hollow shell 18 of bottom installation of main copper hollow shell 17, the inside vice hollow structure 27 that is provided with of main hollow shell 18 one end, main movable rod 15 is in the one end that is located the inside of vice hollow structure 27 passes through hinge installation vice piston plate 28, the other end center of main hollow shell 18 is provided with the vice hollow structure 27 of intercommunication, and internally mounted has the pipeline hole of main first air check valve 29, the other end center of main hollow shell 18 is provided with the vice hollow structure 27 of intercommunication and the bottom of main hollow structure 19, And has the duct hole of the primary air check valve 26 installed therein, and the intake port of the primary air check valve 29 and the exhaust port of the primary air check valve 26 both face the secondary hollow structure 27.

Referring to fig. 2, the gear-mesh-type rotation direction converting mechanism 11 includes a hollow housing 111 for a gear-mesh-type rotation direction converting mechanism, a hollow structure 112 for a gear-mesh-type rotation direction converting mechanism, a bearing 113 for a gear-mesh-type rotation direction converting mechanism, a first rotating shaft 114 for a gear-mesh-type rotation direction converting mechanism, a second rotating shaft 115 for a gear-mesh-type rotation direction converting mechanism, a first bevel gear 116 for a gear-mesh-type rotation direction converting mechanism, and a second bevel gear 117 for a gear-mesh-type rotation direction converting mechanism; a hollow structure 112 for a gear-mesh-type rotation direction converting mechanism is provided inside the hollow housing 111 for a gear-mesh-type rotation direction converting mechanism, a first rotating shaft 114 for a gear-mesh-type rotation direction converting mechanism and a second rotating shaft 115 for a gear-mesh-type rotation direction converting mechanism are respectively attached to the middle portion of both vertical end faces of the hollow housing 111 for a gear-mesh-type rotation direction converting mechanism via a bearing 113 for a gear-mesh-type rotation direction converting mechanism, a first bevel gear 116 for a gear-mesh-type rotation direction converting mechanism and a second bevel gear 117 for a gear-mesh-type rotation direction converting mechanism are respectively attached to the first rotating shaft 114 for a gear-mesh-type rotation direction converting mechanism and the second rotating shaft 115 for a gear-mesh-type rotation direction converting mechanism at one end located inside the hollow structure 112 for a gear-mesh-type rotation direction converting mechanism, and the tooth structures of the first bevel gear 116 for the gear-mesh type rotation direction conversion mechanism and the second bevel gear 117 for the gear-mesh type rotation direction conversion mechanism are meshed with each other; the center of one outer surface of the hollow housing 111 for the gear-mesh type rotation direction conversion mechanism is mounted on the main second support bar 10; the first rotating shaft 114 for the gear-mesh-type rotation direction converting mechanism and the second rotating shaft 115 for the gear-mesh-type rotation direction converting mechanism are fixedly connected to the end portion of the main first rotating shaft 7 and the center of the end surface of the rotating plate 12 at the ends located outside.

Referring to fig. 3, the thread-structured meshing-type terminal distance adjusting mechanism 21 includes a non-conductive hollow rod 211 for the thread-structured meshing-type terminal distance adjusting mechanism, an external thread structure 212 for the thread-structured meshing-type terminal distance adjusting mechanism, a wire hole 213 for the thread-structured meshing-type terminal distance adjusting mechanism, a block-embedding groove structure 214 for the thread-structured meshing-type terminal distance adjusting mechanism, a copper block 215 for the thread-structured meshing-type terminal distance adjusting mechanism, and a wire-embedding groove structure 216 for the thread-structured meshing-type terminal distance adjusting mechanism; the side surface of the non-conductive hollow rod 211 for the thread structure engagement type terminal distance adjusting mechanism is provided with an external thread structure 212 for the thread structure engagement type terminal distance adjusting mechanism, the thread structure engagement type terminal distance adjusting mechanism non-conductive hollow rod 211 is provided with a thread structure engagement type terminal distance adjusting mechanism wire guide hole 213 at the center inside, one end of the thread structure engagement type terminal distance adjustment mechanism wire guide 213 is provided with a thread structure engagement type terminal distance adjustment mechanism block body embedding groove structure 214, a copper block 215 for the thread structure engagement type terminal distance adjusting mechanism is embedded in the block embedding groove structure 214 for the thread structure engagement type terminal distance adjusting mechanism, a lead wire embedding groove structure 216 for the thread structure meshed type binding post distance adjusting mechanism is arranged at the center of one end of the copper block 215 for the thread structure meshed type binding post distance adjusting mechanism; the thread structure-engaged type external thread structure 212 for the binding post distance adjusting mechanism is engaged with the internal thread structure inside the main internal thread hole 20; the structure of one end of the copper block 215 for the thread-structured engaging type terminal distance adjusting mechanism protrudes outward relative to one end of the block-embedding groove structure 214 for the thread-structured engaging type terminal distance adjusting mechanism.

The specific use mode is as follows: during the operation of the invention, a No. 1 conducting wire is arranged on the positive pole of a power supply, then the other end of the No. 1 conducting wire is arranged on the surface of a main binding post 25, then a No. 2 conducting wire is taken, one end of the No. 2 conducting wire is connected with the positive pole of a driving motor in an integral cutting device for cement road construction, then the other end of the No. 2 conducting wire and a meshed binding post distance adjusting mechanism with a thread structure are embedded and fixed by a conducting wire embedding hole 216, then the integral cutting device for cement road construction is arranged on the upper surface of a main part mounting substrate 1, then the device is pushed along the central line of a cement road, when the device is pushed, a rotating wheel 8 rotates, under the linkage action of parts and the action of a connecting rod, a main piston 28 continuously reciprocates, air continuously rushes into an auxiliary hollow structure 19, an auxiliary copper piston plate 23 moves upwards under the action of pressure, when the auxiliary copper piston plate 23 is contacted with the meshed binding post distance adjusting mechanism, the current switch-on, the whole cutting device work is used in the cement road construction, after the whole cutting device work is accomplished in the cement road construction, discharges the air through main valve inside 24, and the part resets, can carry out next removal cutting.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. The utility model provides a linear cutting mechanism motion support is used in cement road construction, includes main part mounting substrate (1), its characterized in that: the side mounting of main part mounting substrate (1) bottom has gyro wheel bracing piece (2), main part mounting substrate (1) upper surface is provided with main bolt hole (3), set up a swiveling wheel groove structure (4) on the plate body of main part mounting substrate (1), the basal surface of main part mounting substrate (1) is being located a main first bracing piece (5) of a side-mounting of swiveling wheel groove structure (4), a main shaft cover (6) is installed to the bottom of main first bracing piece (5), a main first rotation axis (7) is installed through the main bearing in the inside of main shaft cover (6), a main swiveling wheel (8) is installed to the one end of main first rotation axis (7), the periphery of main swiveling wheel (8) cup joints a rubber ring (9), just the level of rubber ring (9) bottom is less than gyro wheel bottom 0.2-0.5 millimeter in gyro wheel bracing piece (2), a gear mesh type rotation direction conversion mechanism (11) is installed at the other end of the main first rotation shaft (7), the outer side of the gear mesh type rotation direction conversion mechanism (11) is connected with the bottom of the main component installation substrate (1) through a main second support rod (10), a rotation shaft end part of the gear mesh type rotation direction conversion mechanism (11) is provided with a rotation plate (12), a fixed rod (13) is installed at the edge of the bottom surface of the rotation plate (12), a rod body of the fixed rod (13) is sleeved inside a sub-shaft sleeve (14) through a main bearing, a main movable rod (15) is installed on the side surface of the sub-shaft sleeve (14), a main third support rod (16) is installed at the bottom of the main component installation substrate (1), a main copper hollow shell (17) is installed at the bottom of the main third support rod (16), a main binding post (25) is installed at the outer side of the main copper hollow shell (17), the device is characterized in that an internal thread hole (20) is formed in the center of the top end of the main copper hollow shell (17), the internal thread hole (20) is meshed with a thread structure meshed type binding post distance adjusting mechanism (21) through a main internal thread structure, a main hollow structure (19) is arranged at the bottom of the internal thread hole (20), an auxiliary copper piston plate (23) is arranged inside the main hollow structure (19), a compressed main spiral spring (22) is arranged on the upper surface of the auxiliary copper piston plate (23), a pipeline hole which is communicated with the bottom of the side surface of the main hollow structure (19) and is internally provided with a main valve core (24) is formed in the side surface of the main copper hollow shell (17), a transverse non-conductive main hollow shell (18) is arranged at the bottom of the main copper hollow shell (17), and an auxiliary hollow structure (27) is arranged inside one end of the main hollow shell (18), the main movable rod (15) is located a hinge-mounted auxiliary piston plate (28) is passed through to the inside one end of vice hollow structure (27), the other end center of main hollow shell (18) is provided with the pipeline hole that communicates vice hollow structure (27), and internally mounted has main first air check valve (29), the other end center of main hollow shell (18) is provided with the pipeline hole that communicates vice hollow structure (27) and main hollow structure (19) bottom, and internally mounted has main second air check valve (26), just the inlet port of main first air check valve (29) and the exhaust port of main second air check valve (26) all face vice hollow structure (27).

2. The linear cutting mechanism motion bracket for cement road construction according to claim 1, characterized in that: the gear-mesh-type rotation direction conversion mechanism (11) comprises a hollow housing (111) for the gear-mesh-type rotation direction conversion mechanism, a hollow structure (112) for the gear-mesh-type rotation direction conversion mechanism, a bearing (113) for the gear-mesh-type rotation direction conversion mechanism, a first rotating shaft (114) for the gear-mesh-type rotation direction conversion mechanism, a second rotating shaft (115) for the gear-mesh-type rotation direction conversion mechanism, a first bevel gear (116) for the gear-mesh-type rotation direction conversion mechanism, and a second bevel gear (117) for the gear-mesh-type rotation direction conversion mechanism.

3. The linear cutting mechanism moving bracket for cement road construction according to claim 2, characterized in that: a hollow structure (112) for the gear-mesh type rotation direction conversion mechanism is arranged in the hollow shell (111) for the gear-mesh type rotation direction conversion mechanism, a first rotating shaft (114) for the gear-mesh type rotation direction conversion mechanism and a second rotating shaft (115) for the gear-mesh type rotation direction conversion mechanism are respectively arranged on the middle part of two vertical end surfaces of the hollow shell (111) for the gear-mesh type rotation direction conversion mechanism through a bearing (113) for the gear-mesh type rotation direction conversion mechanism, a first bevel gear (116) for the gear-mesh type rotation direction conversion mechanism and a second bevel gear (117) for the gear-mesh type rotation direction conversion mechanism are respectively arranged on one end of the hollow structure (112) for the gear-mesh type rotation direction conversion mechanism, and the first bevel gear (116) for the gear-mesh-type rotation direction conversion mechanism and the second bevel gear (117) for the gear-mesh-type rotation direction conversion mechanism are meshed with each other.

4. The linear cutting mechanism motion bracket for cement road construction according to claim 3, characterized in that: the gear-mesh type rotation direction conversion mechanism is mounted on the main second support rod (10) at the center of one outer surface of the hollow housing (111).

5. The linear cutting mechanism motion bracket for cement road construction according to claim 3, characterized in that: the first rotating shaft (114) for the gear mesh type rotating direction converting mechanism and the second rotating shaft (115) for the gear mesh type rotating direction converting mechanism are fixedly connected with the end part of the main first rotating shaft (7) and the end surface center of the rotating plate (12) at one ends positioned outside.

6. The linear cutting mechanism motion bracket for cement road construction according to claim 1, characterized in that: the thread structure meshed type binding post distance adjusting mechanism (21) comprises a non-conductive hollow rod (211) for the thread structure meshed type binding post distance adjusting mechanism, an external thread structure (212) for the thread structure meshed type binding post distance adjusting mechanism, a wire hole (213) for the thread structure meshed type binding post distance adjusting mechanism, a block mosaic groove structure (214) for the thread structure meshed type binding post distance adjusting mechanism, a copper block (215) for the thread structure meshed type binding post distance adjusting mechanism and a wire mosaic groove structure (216) for the thread structure meshed type binding post distance adjusting mechanism.

7. The linear cutting mechanism motion bracket for cement road construction according to claim 6, characterized in that: the side surface of the non-conductive hollow rod (211) for the thread structure meshed type terminal distance adjusting mechanism is provided with an external thread structure (212) for the thread structure meshed type terminal distance adjusting mechanism, the center inside the non-conductive hollow rod (211) for the thread structure meshed type terminal distance adjusting mechanism is provided with a wire hole (213) for the thread structure meshed type terminal distance adjusting mechanism, one end of the wire hole (213) for the thread structure meshed type terminal distance adjusting mechanism is provided with a block embedding groove structure (214) for the thread structure meshed type terminal distance adjusting mechanism, a copper block (215) for the thread structure meshed type terminal distance adjusting mechanism is embedded inside the block embedding groove structure (214) for the thread structure meshed type terminal distance adjusting mechanism, and the center of one end of the copper block (215) for the thread structure meshed type terminal distance adjusting mechanism is provided with a wire for the thread structure meshed type terminal distance adjusting mechanism A damascene trench structure (216).

8. The linear cutting mechanism motion bracket for cement road construction according to claim 7, characterized in that: the thread structure meshed type binding post distance adjusting mechanism is meshed with an internal thread structure inside a main internal thread hole (20) through an external thread structure (212).

9. The linear cutting mechanism motion bracket for cement road construction according to claim 7, characterized in that: one end of the copper block (215) for the thread structure meshed type binding post distance adjusting mechanism protrudes outwards relative to one end of the block embedding groove structure (214) for the thread structure meshed type binding post distance adjusting mechanism.

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