CN111409128A - Mobile control device for mobile cutting device - Google Patents

Abstract

The invention discloses a mobile control device for a mobile cutting device, which comprises a groove type mobile guide rail. The device is matched with a gas control type cutting device for a movable cutting device, can automatically cut a part to be cut by utilizing the pressure of air pressure after moving for a certain distance in a directional mode, is high in automation degree, is mechanical equipment, and long in service life, realizes controllable and stable distance movement by utilizing a worm and gear technology, and has the characteristic of strong control capability.

Description

Mobile control device for mobile cutting device

Technical Field

The invention relates to the technical field of cutting devices, in particular to a mobile control device for a mobile cutting device.

Background

At present, in the aspect of cutting columnar raw materials, a cutting device is generally needed, but when the raw materials with longer distance are cut, the defects of poor control capability, uneven cutting and low efficiency exist.

Disclosure of Invention

The present invention is directed to a mobile control device for a mobile cutting device, so as to solve the problems of the prior art.

In order to achieve the purpose, the invention provides the following technical scheme: a mobile control device for a mobile cutting device comprises a groove type mobile guide rail, wherein a clamping mobile groove structure is arranged at the center of the upper surface of the groove type mobile guide rail, a worm is arranged at two ends inside the groove type mobile guide rail through a main bearing, an outer spiral structure is arranged on a rod body of the worm, the groove type mobile guide rail is provided with a mobile slider in clamping mode inside the clamping mobile groove structure, the rod body of the worm penetrates through a mobile slider block body and is meshed with the mobile slider block body through an inner spiral structure between penetrating positions, a main body shell is arranged at the top of the mobile slider, a driving motor installation shell is arranged at the center of one side of the main body shell, a driving motor is arranged inside the driving motor installation shell, a first component installation space is arranged at one side inside the main body shell, a second component installation space and a third component installation space are arranged at the upper part and the lower part of the main body shell, a shaft body of a motor main shaft in the driving motor penetrates through the main body shell, a gear set meshed type rotating state differentiation mechanism is installed at one end of the motor main shaft, which is positioned in the first component installation space, a main first rotating shaft and a main second rotating shaft, which penetrate through the main body shell, are installed at the end parts of the two rotating shafts at one side of the gear set meshed type rotating state differentiation mechanism, a cylindrical rotary sliding rod clamping and moving mechanism and a gear radius gradually-changing type rotating function conversion mechanism are installed at one ends of the shaft bodies of the main first rotating shaft and the main second rotating shaft, which are positioned in the second component installation space and the third component installation space, a sliding rod moving hole is formed in one side of the second component installation space, a sliding rod is installed in the sliding rod moving hole, and a main third rotating shaft is installed at one rotating shaft end part of the gear radius gradually-changing type rotating function conversion mechanism, the main third rotation axis is located outside one end installation turbine, just through the helical structure meshing between the side of turbine and the body of rod of worm, one side at main body shell top is provided with the main connecting plate structure of integral type structure.

Further, the gear train meshing type rotation state differentiation mechanism includes a housing for the gear train meshing type rotation state differentiation mechanism, a gear installation space for the gear train meshing type rotation state differentiation mechanism, a first rotation shaft for the gear train meshing type rotation state differentiation mechanism, a second rotation shaft for the gear train meshing type rotation state differentiation mechanism, a bearing for the gear train meshing type rotation state differentiation mechanism, a main gear for the gear train meshing type rotation state differentiation mechanism, a sub-gear for the gear train meshing type rotation state differentiation mechanism, a third rotation shaft for the gear train meshing type rotation state differentiation mechanism, and a third rotation shaft for the gear train meshing type rotation state differentiation mechanism; and a gear installation space for the gear set meshing type rotation state differentiation mechanism is arranged in the center of the shell for the gear set meshing type rotation state differentiation mechanism. The gear set meshed type rotating state differentiation mechanism is characterized in that a first rotating shaft for a gear set meshed type rotating state differentiation mechanism is installed at the center of one side of a shell of the gear set meshed type rotating state differentiation mechanism through a bearing for the gear set meshed type rotating state differentiation mechanism, second rotating shafts for two gear set meshed type rotating state differentiation mechanisms are respectively installed at one side of the shell of the gear set meshed type rotating state differentiation mechanism, a main gear for the gear set meshed type rotating state differentiation mechanism is installed at the end part of the first rotating shaft of the gear set meshed type rotating state differentiation mechanism, auxiliary gears for the gear set meshed type rotating state differentiation mechanism are respectively installed at the end parts of the second rotating shafts of the two gear set meshed type rotating state differentiation mechanisms, and the main gear for the gear set meshed type rotating state differentiation mechanism and the auxiliary gear for the gear set meshed type rotating state differentiation mechanism are respectively installed through a third rotating shaft for the gear set meshed type rotating state differentiation mechanism and an The third rotation shaft is mounted inside the side surface of the gear train meshing type rotation state differentiation mechanism housing.

Further, the gear train meshing type rotation state differentiating mechanism is mounted inside the first member mounting space with a housing.

Furthermore, the gear set meshed type rotation state differentiation mechanism is fixedly connected with the end part of the motor spindle through a third rotating shaft, and the end parts of the two gear set meshed type rotation state differentiation mechanisms are respectively and fixedly connected with the end parts of the main second rotating shaft and the main first rotating shaft through the third rotating shaft.

Further, cylindricality rotation type slide bar joint moving mechanism includes cylindricality rotator for cylindricality rotation type slide bar joint moving mechanism, cylindricality rotation type slide bar joint moving mechanism with axis body mounting groove structure, cylindricality rotation type slide bar joint moving mechanism with bent shape groove structure and cylindricality rotation type slide bar joint inserting pole for moving mechanism, cylindricality rotation type slide bar joint moving mechanism is provided with axis body mounting groove structure for cylindricality rotation type slide bar joint moving mechanism with one end center of cylindricality rotator, the internally mounted of cylindricality rotation type slide bar joint moving mechanism with axis body mounting groove structure has the axis body of main first rotation axis one end, cylindricality rotation type slide bar joint moving mechanism is provided with cylindricality rotation type slide bar joint moving mechanism with bent shape groove structure for moving mechanism's circumference side, a internally mounted cylindricality rotation type slide bar joint moving mechanism for cylindricality rotation type slide bar joint moving mechanism with bent shape groove structure With an insertion rod.

Furthermore, the curved groove structure for the cylindrical rotary sliding rod clamping moving mechanism is a trapezoidal structure with an outwardly-expanded ground surface after being expanded.

Furthermore, the end of the inserting rod for the cylindrical rotary sliding rod clamping moving mechanism is fixedly connected with the rod body in the middle of the sliding rod.

Further, the gear radius step-change type rotational function conversion mechanism includes a hollow housing for the gear radius step-change type rotational function conversion mechanism, a hollow structure for the gear radius step-change type rotational function conversion mechanism, a first rotating shaft for the gear radius step-change type rotational function conversion mechanism, a bearing for the gear radius step-change type rotational function conversion mechanism, a second rotating shaft for the gear radius step-change type rotational function conversion mechanism, a third rotating shaft for the gear radius step-change type rotational function conversion mechanism, a first gear for the gear radius step-change type rotational function conversion mechanism, a second gear for the gear radius step-change type rotational function conversion mechanism, a third gear for the gear radius step-change type rotational function conversion mechanism, and a fourth gear for the gear radius step-change type rotational function conversion mechanism; a hollow structure for the gear radius gradually-changing type rotary function conversion mechanism is arranged in the hollow shell for the gear radius gradually-changing type rotary function conversion mechanism, a first rotary shaft for the gear radius gradually-changing type rotary function conversion mechanism is arranged at the bottom center of the hollow shell for the gear radius gradually-changing type rotary function conversion mechanism through a bearing for the gear radius gradually-changing type rotary function conversion mechanism, a third rotary shaft for the gear radius gradually-changing type rotary function conversion mechanism is arranged at the top center of the hollow shell for the gear radius gradually-changing type rotary function conversion mechanism through a bearing for the gear radius gradually-changing type rotary function conversion mechanism, a second rotary shaft for the gear radius gradually-changing type rotary function conversion mechanism is arranged at the side surface of the hollow shell for the gear radius gradually-changing type rotary function conversion mechanism through a bearing for the gear radius gradually-changing type rotary function conversion mechanism, a second gear for the gear radius gradually-changing type rotation function conversion mechanism and a third gear for the gear radius gradually-changing type rotation function conversion mechanism are mounted on a shaft body of the second rotation shaft for the gear radius gradually-changing type rotation function conversion mechanism, the top end of the first rotating shaft for the gear radius gradually-changing type rotating function converting mechanism and the bottom end of the third rotating shaft for the gear radius gradually-changing type rotating function converting mechanism are respectively provided with a first gear for the gear radius gradually-changing type rotating function converting mechanism and a fourth gear for the gear radius gradually-changing type rotating function converting mechanism, and the first gear for the gear radius gradually-changing type rotating function converting mechanism is meshed with the tooth structure between the second gear for the gear radius gradually-changing type rotating function converting mechanism, and the third gear for the gear radius gradually-changing type rotating function converting mechanism is meshed with the tooth structure between the fourth gear for the gear radius gradually-changing type rotating function converting mechanism.

Further, the first gear reference circle for the gear radius gradually-changing type rotational function conversion mechanism has a structural radius smaller than that of the second gear reference circle for the gear radius gradually-changing type rotational function conversion mechanism, the second gear reference circle for the gear radius gradually-changing type rotational function conversion mechanism has a structural radius larger than that of the third gear reference circle for the gear radius gradually-changing type rotational function conversion mechanism, and the third gear for the gear radius gradually-changing type rotational function conversion mechanism has a structural radius smaller than that of the fourth gear reference circle for the gear radius gradually-changing type rotational function conversion mechanism.

Further, the end of the first rotating shaft for the gear radius gradually-changing type rotating function converting mechanism and the end of the third rotating shaft for the gear radius gradually-changing type rotating function converting mechanism are fixedly connected with the ends of the main third rotating shaft and the main second rotating shaft respectively.

Compared with the prior art, the invention has the beneficial effects that: the invention is used with a gas control type cutting device for a movable cutting device, can automatically cut a part to be cut by utilizing the pressure of air pressure after moving for a certain distance in a directional way, has high automation degree, is mechanical equipment, has long service life, realizes controllable and stable distance movement by utilizing a worm and gear technology, has the characteristic of strong control capability, has a gear set meshed type rotating state differentiation mechanism, can realize multiple purposes, has a cylindrical rotary slide bar clamping and moving mechanism, can make a rod body do stable reciprocating movement by utilizing a curved groove structure and an inserted slide bar in a rotating state, thereby performing the opening and closing function on a vent hole of high-pressure air and realizing controllable cutting time, and has a gear radius gradually-changing type rotating function conversion mechanism, the rotating strength can be reduced, the rotating speed can be improved, and the moving speed can be accelerated.

Drawings

FIG. 1 is a schematic view of a mobile control device for a mobile cutting apparatus according to the present invention;

FIG. 2 is a schematic structural diagram of a gear-meshing type rotating state differentiation mechanism in a mobile control device for a mobile cutting device according to the present invention;

FIG. 3 is a schematic structural view of a cylindrical rotary sliding rod clamping moving mechanism in a moving control device for a movable cutting device according to the present invention when it is deployed;

FIG. 4 is a schematic structural diagram of a gear radius-changing type rotating function converting mechanism in a mobile control device for a mobile cutting device according to the present invention;

in the figure: 1, a groove type moving guide rail, 2, a clamping moving groove structure, 3, a moving slide block, 4, a worm, 5, a main body housing, 6, a driving motor mounting housing, 7, a driving motor, 8, a motor spindle, 9, a first component mounting space, 10, a second component mounting space, 11, a third component mounting space, 12, a slide rod moving hole, 13, a gear set meshing type rotation state differentiation mechanism, 131, a gear set meshing type rotation state differentiation mechanism housing, 132, a gear set meshing type rotation state differentiation mechanism gear mounting space, 133, a gear set meshing type rotation state differentiation mechanism first rotating shaft, 134, a gear set meshing type rotation state differentiation mechanism second rotating shaft, 135, a gear set meshing type rotation state differentiation mechanism bearing, 136, a gear set meshing type rotation state differentiation mechanism main gear, 137, a gear set meshing type rotation state differentiation mechanism sub-gear, 138, a third rotation shaft for a gear train meshing type rotation state differentiation mechanism, 139, a third rotation shaft for a gear train meshing type rotation state differentiation mechanism, 14, a main first rotation shaft, 15, a main second rotation shaft, 16, a cylindrical rotary slide bar click movement mechanism, 161, a cylindrical rotary body for a cylindrical rotary slide bar click movement mechanism, 162, a shaft body mounting groove structure for a cylindrical rotary slide bar click movement mechanism, 163, a curved groove structure for a cylindrical rotary slide bar click movement mechanism, 164, an insertion rod, 17, a gear radius step-change type rotation function conversion mechanism, 171, a hollow housing for a gear radius step-change type rotation function conversion mechanism, 172, a hollow structure for a gear radius step-change type rotation function conversion mechanism, 173, a first rotation shaft for a gear radius step-change type rotation function conversion mechanism, 174, a bearing for a gear radius step-change type rotational function conversion mechanism, 175, a second rotational shaft for a gear radius step-change type rotational function conversion mechanism, 176, a third rotational shaft for a gear radius step-change type rotational function conversion mechanism, 177, a first gear for a gear radius step-change type rotational function conversion mechanism, 178, a second gear for a gear radius step-change type rotational function conversion mechanism, 179, a third gear for a gear radius step-change type rotational function conversion mechanism, 1710, a fourth gear for a gear radius step-change type rotational function conversion mechanism, 18, a slider, 19, main third rotational shafts, 20, a turbine, 21, and a main connecting plate structure.

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: including recess formula movable guide 1, 1 upper surface center of recess formula movable guide is provided with joint and removes groove structure 2, a worm 4 is passed through at the inside both ends of recess formula movable guide 1, be provided with outer helical structure on the body of rod of worm 4, recess formula movable guide 1 is lieing in the joint removes groove structure 2's inside joint one and removes slider 3, the body of rod of worm 4 runs through and removes the slider 3 block, and both pass through the meshing of interior helical structure between the position, remove a main body cover 5 of slider 3's top installation, a driving motor installation shell 6 of one side center installation of main body cover 5, a driving motor 7 of inside installation of driving motor installation shell 6, the inside one side of main body cover 5 is provided with first part installation space 9, the inside opposite side of main body cover 5 is provided with second part installation space 10 and the empty third part installation space that set up and down two A shaft body 11, a motor spindle 8 of the driving motor 7 penetrates through the main body casing 5, a gear set meshed type rotation state differentiation mechanism 13 is installed at one end of the motor spindle 8 positioned in the first component installation space 9, a main first rotation shaft 14 and a main second rotation shaft 15 penetrating through the main body casing 5 are respectively installed at two rotation shaft end portions on one side of the gear set meshed type rotation state differentiation mechanism 13, a cylindrical rotary slide bar clamping movement mechanism 16 and a gear radius gradually-changing type rotation function conversion mechanism 17 are respectively installed at one ends of the shaft bodies of the main first rotation shaft 14 and the main second rotation shaft 15 positioned in the second component installation space 10 and the third component installation space 11, a slide bar movement hole 12 is formed in one side of the second component installation space 10 in the main body casing 5, a slide bar 18 is installed in the slide bar movement hole 12, a third main rotating shaft 19 is installed at one end of a rotating shaft of the gear radius gradually-changing type rotating function converting mechanism 17, a worm wheel 20 is installed at one end, located outside, of the third main rotating shaft 19, the side face of the worm wheel 20 is meshed with the rod body of the worm 4 through a spiral structure, and a main connecting plate structure 21 of an integrated structure is arranged on one side of the top of the main shell 5.

Referring to fig. 2, the gear train meshing type rotation state differentiation mechanism 13 includes a gear train meshing type rotation state differentiation mechanism housing 131, a gear installation space 132 for the gear train meshing type rotation state differentiation mechanism, a first rotation shaft 133 for the gear train meshing type rotation state differentiation mechanism, a second rotation shaft 134 for the gear train meshing type rotation state differentiation mechanism, a bearing 135 for the gear train meshing type rotation state differentiation mechanism, a main gear 136 for the gear train meshing type rotation state differentiation mechanism, a sub-gear 137 for the gear train meshing type rotation state differentiation mechanism, a third rotation shaft 138 for the gear train meshing type rotation state differentiation mechanism, and a third rotation shaft 139 for the gear train meshing type rotation state differentiation mechanism; a gear mounting space 132 for the gear train meshing type rotation state differentiation mechanism is provided in the center of the gear train meshing type rotation state differentiation mechanism housing 131. A first rotating shaft 133 for a gear-set meshing type rotating state differentiation mechanism is installed at the center of one side of a housing 131 for the gear-set meshing type rotating state differentiation mechanism through a bearing 135 for the gear-set meshing type rotating state differentiation mechanism, second rotating shafts 134 for two gear-set meshing type rotating state differentiation mechanism are respectively installed at one side of the housing 131 for the gear-set meshing type rotating state differentiation mechanism, a main gear 136 for the gear-set meshing type rotating state differentiation mechanism is installed at the end part of the first rotating shaft 133 for the gear-set meshing type rotating state differentiation mechanism, sub-gears 137 for the gear-set meshing type rotating state differentiation mechanism are respectively installed at the end parts of the second rotating shafts 134 for the two gear-set meshing type rotating state differentiation mechanisms, and the end parts of the main gear 136 for the gear-set meshing type rotating state differentiation mechanism and the sub-gears 137 for the gear-set meshing type rotating state differentiation mechanism are respectively through a third rotating shaft A third rotation shaft 139 for meshing type rotation state differentiation mechanism is attached to the inside of the side surface of the housing 131 for meshing type rotation state differentiation mechanism of gear train; the gear train meshing type rotational state differentiating mechanism case 131 is installed inside the first member installation space 9; the gear set meshing type rotation state differentiation mechanism is fixedly connected with the end part of the motor spindle 8 through a third rotating shaft 138, and the end parts of the two gear set meshing type rotation state differentiation mechanisms are fixedly connected with the end parts of the main second rotating shaft 15 and the main first rotating shaft 14 through a third rotating shaft 139 respectively.

Referring to fig. 3, the cylindrical rotary slide bar clamping moving mechanism 16 includes a cylindrical rotating body 161 for the cylindrical rotary slide bar clamping moving mechanism, a shaft body mounting groove structure 162 for the cylindrical rotary slide bar clamping moving mechanism, a curved groove structure 163 for the cylindrical rotary slide bar clamping moving mechanism, and an insertion rod 164 for the cylindrical rotary slide bar clamping moving mechanism, wherein the shaft body mounting groove structure 162 for the cylindrical rotary slide bar clamping moving mechanism is disposed at the center of one end of the cylindrical rotating body 161 for the cylindrical rotary slide bar clamping moving mechanism, a shaft body at one end of the main first rotating shaft 14 is mounted inside the shaft body mounting groove structure 162 for the cylindrical rotary slide bar clamping moving mechanism, the curved groove structure 163 for the cylindrical rotary slide bar clamping moving mechanism is disposed on the circumferential side surface of the cylindrical rotating body 161 for the cylindrical rotary slide bar clamping moving mechanism, a cylindrical rotary sliding rod clamping moving mechanism insert rod 164 is arranged in the curved groove structure 163 for the cylindrical rotary sliding rod clamping moving mechanism; the curved groove structure 163 for the cylindrical rotary sliding rod clamping moving mechanism is a trapezoid structure with an outwardly-expanded ground surface after being expanded; the end of the insertion rod 164 for the cylindrical rotary sliding rod clamping moving mechanism is fixedly connected with the rod body in the middle of the sliding rod 18.

Referring to fig. 4, the gear radius gradually-varying type rotational function converting mechanism 17 includes a hollow housing 171 for the gear radius gradually-varying type rotational function converting mechanism, a hollow structure 172 for the gear radius gradually-varying type rotational function converting mechanism, a first rotating shaft 173 for the gear radius gradually-varying type rotational function converting mechanism, a bearing 174 for the gear radius gradually-varying type rotational function converting mechanism, a second rotating shaft 175 for the gear radius gradually-varying type rotational function converting mechanism, a third rotating shaft 177 for the gear radius gradually-varying type rotational function converting mechanism, a first gear 178 for the gear radius gradually-varying type rotational function converting mechanism, a second gear 179 for the gear radius gradually-varying type rotational function converting mechanism, a third gear 1710 for the gear radius gradually-varying type rotational function converting mechanism, and a fourth gear 1711 for the gear radius gradually-varying type rotational function converting mechanism; a hollow structure 172 for a gear radius step-by-step type rotational function conversion mechanism is provided inside the hollow housing 171 for a gear radius step-by-step type rotational function conversion mechanism, a first rotational shaft 173 for a gear radius step-by-step type rotational function conversion mechanism is attached to the center of the bottom of the hollow housing 171 for a gear radius step-by-step type rotational function conversion mechanism through a bearing 174 for a gear radius step-by-step type rotational function conversion mechanism, a third rotational shaft 177 for a gear radius step-by-step type rotational function conversion mechanism is attached to the center of the top of the hollow housing 171 for a gear radius step-by-step type rotational function conversion mechanism through a bearing 174 for a gear radius step-by-step type rotational function conversion mechanism, a second rotational shaft for a gear radius step-by-step type rotational function conversion mechanism is attached to the side of the hollow housing 171 for a gear radius step-by step type rotational function conversion mechanism through a bearing 174, 175, gear radius progressively changes formula second rotation axis for rotation function conversion mechanism, install gear radius progressively changes formula second gear 179 for rotation function conversion mechanism and gear radius progressively changes formula third gear 1710 for rotation function conversion mechanism on 175's the axis body, gear radius progressively changes formula for rotation function conversion mechanism first rotation axis 173 top with gear radius progressively changes formula for rotation function conversion mechanism first gear 178 and gear radius progressively changes formula for rotation function conversion mechanism fourth gear 1711 for rotation function conversion mechanism are installed respectively to gear radius progressively changes formula for rotation function conversion mechanism bottom with third rotation axis 177, just gear radius progressively changes formula for rotation function conversion mechanism and meshes with the tooth structure between first gear 178 and gear radius progressively changes formula for rotation function conversion mechanism second gear 179, gear radius progressively changes formula for rotation function conversion mechanism third gear 1710 and gear radius progressively changes formula for rotation function conversion mechanism tooth structure between fourth gear 1711 Structure engagement; the structure radius of the first gear 178 reference circle for the gear radius incremental change type rotational function conversion mechanism is smaller than the structure radius of the second gear 179 reference circle for the gear radius incremental change type rotational function conversion mechanism, the structure radius of the second gear 179 reference circle for the gear radius incremental change type rotational function conversion mechanism is larger than the structure radius of the third gear 1710 reference circle for the gear radius incremental change type rotational function conversion mechanism, and the structure radius of the third gear 1710 for the gear radius incremental change type rotational function conversion mechanism is smaller than the structure radius of the fourth gear 1711 reference circle for the gear radius incremental change type rotational function conversion mechanism; the end of the first rotating shaft 173 for the gear radius changing type rotating function converting mechanism and the end of the third rotating shaft 177 for the gear radius changing type rotating function converting mechanism are fixedly connected to the ends of the main third rotating shaft 19 and the main second rotating shaft 15, respectively.

The specific use mode is as follows: in the work of the invention, the device is butted with a gas control type cutting device for a mobile cutting device, and the groove type moving guide rail 1 of the device is laid on one side of the raw material to be cut, then the driving motor 7 is turned on, under the linkage action of the components, at the moment, the worm wheel 20 rotates to drive the worm 4 to rotate, meanwhile, two ends of the worm 4 are fixed in the groove type moving guide rail 1 through the main bearing, meanwhile, the external spiral structure in the worm 4 is meshed with the clamping slide block 3 through the internal spiral structure, therefore, the clamping sliding block 3 drives the main body shell 1 to move, when the clamping sliding block moves, when the cylindrical rotary type sliding rod clamping moving mechanism 16 rotates for a circle, the sliding rod 18 changes to do telescopic movement once, and the gas control type cutting device for the movable cutting device can perform a cutting action once by telescopic movement once, so that reciprocating can realize equidistant cutting at a fixed point.

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 (10)

1. The utility model provides a portable for cutting device movement control device, includes recess formula movable guide (1), its characterized in that: the groove type movable guide rail is characterized in that a clamping movable groove structure (2) is arranged at the center of the upper surface of a groove type movable guide rail (1), a worm (4) is installed at two ends of the inner part of the groove type movable guide rail (1) through a main bearing, an outer spiral structure is arranged on a rod body of the worm (4), the groove type movable guide rail (1) is connected with a movable sliding block (3) in a clamping mode in the inner part of the clamping movable groove structure (2), the rod body of the worm (4) penetrates through a block body of the movable sliding block (3), the worm body and the movable sliding block are meshed through the inner spiral structure between penetrating parts, a main shell (5) is installed at the top of the movable sliding block (3), a driving motor installation shell (6) is installed at the center of one side of the main shell (5), a driving motor (7) is installed in the driving motor installation shell (6), and a first part installation space (, the other side in main body cover (5) inside is provided with second part installation space (10) and third part installation space (11) that two set up from top to bottom, the axis body of motor main shaft (8) among driving motor (7) runs through main body cover (5), just motor main shaft (8) are lieing in one end installation a gear train engaged type rotation state differentiation mechanism (13) inside first part installation space (9), the two rotation axis tip of gear train engaged type rotation state differentiation mechanism (13) one side are installed respectively and are run through main body cover (5) main first rotation axis (14) and main second rotation axis (15), just the axis body of main first rotation axis (14) and main second rotation axis (15) is lieing in the one end in second part installation space (10) and third part installation space (11) inside is installed cylindricality rotation type slide bar joint moving mechanism (16) and gear radius and is progressively changed formula rotation function conversion and is transferred respectively Mechanism (17), the inside of main body cover (5) is lieing in one side of second part installation space (10) is provided with slide bar removal hole (12), a internally mounted slide bar (18) of slide bar removal hole (12), a main third rotation axis (19) of gear radius gradual change formula rotation function conversion mechanism's (17) a rotation axis tip installation, a turbine (20) is installed in the one end that lies in the outside in main third rotation axis (19), just through the helical structure meshing between the side of turbine (20) and the body of rod of worm (4), one side at main body cover (5) top is provided with the main connecting plate structure (21) of integral type structure.

2. The movement control device for a mobile cutting apparatus according to claim 1, wherein: the gear set meshing type rotation state differentiation mechanism (13) comprises a housing (131) for the gear set meshing type rotation state differentiation mechanism, a gear installation space (132) for the gear set meshing type rotation state differentiation mechanism, a first rotating shaft (133) for the gear set meshing type rotation state differentiation mechanism, a second rotating shaft (134) for the gear set meshing type rotation state differentiation mechanism, a bearing (135) for the gear set meshing type rotation state differentiation mechanism, a main gear (136) for the gear set meshing type rotation state differentiation mechanism, a secondary gear (137) for the gear set meshing type rotation state differentiation mechanism, a third rotating shaft (138) for the gear set meshing type rotation state differentiation mechanism and a third rotating shaft (139) for the gear set meshing type rotation state differentiation mechanism; a gear mounting space (132) for the gear meshing type rotation state differentiation mechanism is arranged at the center of the gear meshing type rotation state differentiation mechanism housing (131). A first rotating shaft (133) for a gear set meshing type rotating state differentiation mechanism is arranged at the center of one side of a gear set meshing type rotating state differentiation mechanism shell (131) through a gear set meshing type rotating state differentiation mechanism bearing (135), second rotating shafts (134) for two gear set meshing type rotating state differentiation mechanisms are respectively arranged at one sides of the gear set meshing type rotating state differentiation mechanism shell (131), a main gear (136) for the gear set meshing type rotating state differentiation mechanism is arranged at the end part of the gear set meshing type rotating state differentiation mechanism first rotating shaft (133), auxiliary gears (137) for the gear set meshing type rotating state differentiation mechanism are respectively arranged at the end parts of the two gear set meshing type rotating state differentiation mechanisms second rotating shafts (134), and the gear set meshing type rotating state differentiation mechanism main gear (136) and the gear set meshing type rotating state differentiation mechanism auxiliary gears (137) are respectively arranged at the end parts through the gear sets A third rotation shaft (138) for a meshing type rotation state differentiation mechanism and a third rotation shaft (139) for a gear train meshing type rotation state differentiation mechanism are attached to the inside of the side surface of a housing (131) for a gear train meshing type rotation state differentiation mechanism.

3. The movement control device for a mobile cutting apparatus according to claim 2, wherein: the gear train meshing type rotation state differentiation mechanism housing (131) is installed inside the first member installation space (9).

4. The movement control device for a mobile cutting apparatus according to claim 2, wherein: the gear set meshed type rotation state differentiation mechanism is fixedly connected with the end part of the motor spindle (8) through a third rotating shaft (138), and the end parts of the gear set meshed type rotation state differentiation mechanism and the motor spindle are respectively fixedly connected with the end parts of the main second rotating shaft (15) and the main first rotating shaft (14) through a third rotating shaft (139).

5. The movement control device for a mobile cutting apparatus according to claim 1, wherein: the cylindrical rotary slide bar clamping moving mechanism (16) comprises a cylindrical rotary body (161) for the cylindrical rotary slide bar clamping moving mechanism, a shaft body mounting groove structure (162) for the cylindrical rotary slide bar clamping moving mechanism, a curved groove structure (163) for the cylindrical rotary slide bar clamping moving mechanism and an insertion rod (164) for the cylindrical rotary slide bar clamping moving mechanism, wherein the shaft body mounting groove structure (162) for the cylindrical rotary slide bar clamping moving mechanism is arranged at the center of one end of the cylindrical rotary body (161) for the cylindrical rotary slide bar clamping moving mechanism, a shaft body at one end of a main first rotating shaft (14) is arranged inside the shaft body mounting groove structure (162) for the cylindrical rotary slide bar clamping moving mechanism, the curved groove structure (163) for the cylindrical rotary slide bar clamping moving mechanism is arranged on the circumferential side surface of the cylindrical rotary body (161) for the cylindrical rotary slide bar clamping moving mechanism, the inside of curved groove structure (163) for the cylindrical rotary sliding rod clamping moving mechanism is provided with a cylindrical rotary sliding rod clamping moving mechanism insertion rod (164).

6. The movement control device for a mobile cutting apparatus according to claim 5, wherein: the cylindrical rotary sliding rod clamping moving mechanism is of a trapezoid structure with a curved groove structure (163) expanding outwards from the ground surface after being expanded.

7. The movement control device for a mobile cutting apparatus according to claim 5, wherein: the end part of the inserting rod (164) for the cylindrical rotary sliding rod clamping moving mechanism is fixedly connected with the rod body in the middle of the sliding rod (18).

8. The movement control device for a mobile cutting apparatus according to claim 1, wherein: the gear radius gradually-changing type rotation function conversion mechanism (17) comprises a hollow shell (171) for the gear radius gradually-changing type rotation function conversion mechanism, a hollow structure (172) for the gear radius gradually-changing type rotation function conversion mechanism, a first rotating shaft (173) for the gear radius gradually-changing type rotation function conversion mechanism, a bearing (174) for the gear radius gradually-changing type rotation function conversion mechanism, and a second rotating shaft (175) for the gear radius gradually-changing type rotation function conversion mechanism, a third rotation shaft (177) for a gear radius gradually-changing type rotation function conversion mechanism, a first gear (178) for a gear radius gradually-changing type rotation function conversion mechanism, a second gear (179) for a gear radius gradually-changing type rotation function conversion mechanism, a third gear (1710) for a gear radius gradually-changing type rotation function conversion mechanism, and a fourth gear (1711) for a gear radius gradually-changing type rotation function conversion mechanism; a hollow structure (172) for a gear radius gradually-changing type rotary function conversion mechanism is arranged in the hollow shell (171) for the gear radius gradually-changing type rotary function conversion mechanism, a first rotary shaft (173) for the gear radius gradually-changing type rotary function conversion mechanism is arranged at the bottom center of the hollow shell (171) for the gear radius gradually-changing type rotary function conversion mechanism through a bearing (174) for the gear radius gradually-changing type rotary function conversion mechanism, a third rotary shaft (177) for the gear radius gradually-changing type rotary function conversion mechanism is arranged at the top center of the hollow shell (171) for the gear radius gradually-changing type rotary function conversion mechanism through the bearing (174) for the gear radius gradually-changing type rotary function conversion mechanism, and a second rotary shaft (174) for the gear radius gradually-changing type rotary function conversion mechanism is arranged at the side surface of the hollow shell (171) for the gear radius gradually-changing type rotary function conversion mechanism through the bearing (174) for the gear radius gradually-changing type rotary function conversion mechanism A shaft (175), a second gear (179) for the gear radius incremental change type rotation function conversion mechanism and a third gear (1710) for the gear radius incremental change type rotation function conversion mechanism are installed on the shaft body of the second rotation shaft (175) for the gear radius incremental change type rotation function conversion mechanism, the gear radius incremental change type rotation function conversion mechanism uses a first rotation shaft (173) top end and the gear radius incremental change type rotation function conversion mechanism uses a bottom end of a third rotation shaft (177) to install a first gear (178) for the gear radius incremental change type rotation function conversion mechanism and a fourth gear (1711) for the gear radius incremental change type rotation function conversion mechanism respectively, and the gear radius incremental change type rotation function conversion mechanism uses a first gear (178) and a gear radius incremental change type rotation function conversion mechanism uses a tooth structure meshing between the second gears (179), and the tooth structures between the third gear (1710) for the gear radius gradually-changing type rotating function conversion mechanism and the fourth gear (1711) for the gear radius gradually-changing type rotating function conversion mechanism are meshed.

9. The movement control apparatus for a mobile cutting apparatus according to claim 8, wherein: the structure radius of gear radius formula of progressively becoming for rotatory function conversion mechanism first gear (178) reference circle is less than the structure radius of gear radius formula of progressively becoming for rotatory function conversion mechanism second gear (179) reference circle, the structure radius of gear radius formula of progressively becoming for rotatory function conversion mechanism second gear (179) reference circle is greater than the structure radius of gear radius formula of progressively becoming for rotatory function conversion mechanism third gear (1710) reference circle, gear radius formula of progressively becoming for rotatory function conversion mechanism third gear (1710) is less than the structure radius of gear radius formula of progressively becoming for rotatory function conversion mechanism fourth gear (1711) reference circle.

10. The movement control apparatus for a mobile cutting apparatus according to claim 8, wherein: the end of the first rotating shaft (173) for the gear radius gradually-changing type rotating function conversion mechanism and the end of the third rotating shaft (177) for the gear radius gradually-changing type rotating function conversion mechanism are respectively fixedly connected with the ends of the main third rotating shaft (19) and the main second rotating shaft (15).

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