CN109356393B - Building site atress adds protects wire device that recycles - Google Patents

Abstract

The invention discloses a construction site stress-reinforced wire guide device for recycling, which structurally comprises a stress-reinforced wire guide sleeve, an insulating shell, a connecting port and a spindle core, wherein the right end of the stress-reinforced wire guide sleeve penetrates through the left end of the insulating shell, the stress-reinforced wire guide sleeve comprises a soft protective shell, a stress main sensor, a top protective layer, an inner protective strip and a wire placing grid, the wire placing grid is arranged in the soft protective shell and is positioned on the same axis, two top protective layers are in a group, and the stress main sensor is arranged between the two top protective layers, so that the stress main sensor can push a semi-arc push rod to assist the top protective layer to be propped against the inside of the soft protective shell by the pushing force, the outer shell is difficult to extrude the wire placing grid in the inner part, when the force is too large, an extrusion rotating shaft is extruded inwards, a tilting wheel is pushed, and an inclined pulling follow-on rod pulls the inner protective strip to protect the outer shell of the wire placing grid, prevent that external power is too big, cause the damage to the wire of wire arrangement check inside.

Description

Building site atress adds protects wire device that recycles

Technical Field

The invention belongs to the field of building construction, and particularly relates to a wire guide device for stress reinforcement and recycling in a building site.

Background

The existing construction sites have various required leads, and some leads are installed for temporary and convenient use and then need to be withdrawn until the next time when required, and the leads are taken out for continuous use, and the process is repeated.

Based on the findings of the inventor, the existing construction site wire sleeve mainly has the following defects, such as:

when the wire is exposed to the air above the sand for the most part of the use, the life of the wire is reduced when the worker walks on the surface, causing the wire to rub against the sand, thus damaging its casing and even endangering the inside.

Therefore, a wire guiding device for force-bearing protection recycling in construction site needs to be provided

Disclosure of Invention

In order to solve the problem that the service life of the wire is reduced when the wire is exposed to the air on the sand and the personnel on the construction site walk on the surface, so that the wire can rub against the sand and the shell of the wire is damaged and even the inside of the wire is endangered.

The invention relates to a purpose and an effect of a wire guide device for cyclic use in construction site stress protection, which are achieved by the following specific technical means:

the structure of the cable comprises a stress reinforcing wire sleeve, an insulating shell, a connecting port and a spindle core.

The stress reinforcement wire sleeve is characterized in that the right end of the stress reinforcement wire sleeve penetrates through the inside of the left end of the insulating shell, the linking port is installed inside the insulating shell and located on the same axis, and the spindle core penetrates through the inside of the insulating shell and is connected with the stress reinforcement wire sleeve.

The stress reinforcement wire sleeve comprises a soft protective shell, a stress main sensing body, a top protective layer, an inner protective strip and a wire placing grid, the wire placing grid is installed inside the soft protective shell and located on the same axis, the two top protective layers are a group and the stress main sensing body is installed between the two top protective layers, and the inner protective strip is located below the stress main sensing body and located on the outer surface of the wire placing grid.

As a further improvement of the invention, the soft protective shell comprises an auxiliary dragging block, a semi-static rotating shaft, a semi-arc push rod, an extrusion rotating shaft, an auxiliary pushing wheel, a tilting wheel, tilting rods, an inclined pulling rod, an extension stressed rod and a connecting shaft, wherein the semi-static rotating shaft penetrates through the auxiliary dragging block and is positioned in the middle of the auxiliary dragging block, the top protective layer is attached to the surface of one end, away from the semi-static rotating shaft, of the auxiliary dragging block, the two semi-arc push rods are in a group, the extrusion rotating shaft penetrates through the semi-arc push rods, the auxiliary pushing wheels are installed inside two ends of a stressed main sensing body, the two tilting rods are in a group, the tilting wheel penetrates through the tilting rods, the connecting shaft is installed at one end, away from the tilting wheels, the extension stressed main sensing body is in a structure with two semi-convex parts and a relatively low middle convex part, the semi-arc push rod is in a semi-arc structure, the seesaw rod is of a micro-arc structure.

As a further improvement of the present invention, the stressed main sensor includes a stressed outer body, a fixed central shaft and an auxiliary friction wheel, the fixed central shaft is welded to the inner bottom end of the stressed outer body, the fixed central shaft penetrates through the inner part of the auxiliary friction wheel and is located on the same axis, and a groove at the bottom of the stressed outer body is of a C-shaped structure.

As a further improvement of the invention, the extrusion rotating shaft comprises a mounting groove, a fixed block, a threaded rod, a return spring, a threaded sleeve and a fixed mounting body, wherein the return spring is mounted in the mounting groove, the fixed mounting bodies are vertically welded at the left end and the right end of the return spring, the threaded sleeve is positioned in the mounting groove and positioned on the same axis, the fixed block is welded at the right end of the threaded rod, and the return spring and the two fixed mounting bodies are combined into an I-shaped structure.

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

when its atress is consolidated wire cover and is stepped on by external power, external power of stepping on will extrude its atress main body of feeling, make the atress main body of feeling can push the supplementary top protective layer of half arc push rod through the power that promotes and support inside the software protecting crust, make the shell receive extruded power, be difficult to extrude inside wire and put the check, work as the power too big, its extrusion rotation axis is still when inwards extruding, will promote the perk driving wheel, make slope pulling rod in the pulling action to follow the trend the interior protective strip and put the check shell to the wire and protect, prevent that external power is too big, put the inside wire of check and cause the damage to the wire.

Drawings

Fig. 1 is a schematic structural diagram of a construction site stress-protecting wire recycling device of the invention.

Fig. 2 is a front view of the internal structure of a force-reinforced wire sheath according to the present invention.

FIG. 3 is a schematic diagram of a right-view internal structure of a soft shell according to the present invention.

Fig. 4 is a schematic front view of the internal structure of the force-bearing main sensor of the present invention.

FIG. 5 is a right-view internal structural diagram of an extrusion rotary shaft according to the present invention.

In the figure: a stress reinforcement wire sleeve-1, an insulating shell-2, a connecting port-3, a main shaft core-4, a soft protective shell-11, a stress main sensor-12, a top protective layer-13, an inner protective strip-14, a wire placing grid-15, an auxiliary dragging block-111, a semi-static rotating shaft-112, a semi-arc push rod-113, an extrusion rotating shaft-114 and a pushing auxiliary wheel-115, the device comprises a tilting wheel-116, a tilting rod-117, an inclined pulling rod-118, an extension stress rod-119, a connecting shaft-1110, a stress outer body-12 a, a fixed central shaft-12 b, an auxiliary friction wheel-12 c, a mounting groove-114 a, a fixed block-114 b, a threaded rod-114 c, a return spring-114 d, a threaded sleeve-114 e and a fixed mounting body-114 f.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example (b):

as shown in figures 1 to 5:

the invention provides a wire device for recycling in a stress-reinforced manner in a construction site, which structurally comprises a stress-reinforced wire sleeve 1, an insulating shell 2, a connecting port 3 and a spindle core 4.

The right end of the stress reinforcement wire sleeve 1 penetrates through the inside of the left end of the insulating shell 2, the linking port 3 is installed inside the insulating shell 2 and located on the same axis, and the spindle core 4 penetrates through the inside of the insulating shell 2 and is connected with the stress reinforcement wire sleeve 1.

Stress reinforcement wire sleeve 1 includes that software protecting crust 11, atress are main to be felt body 12, top protecting layer 13, interior protecting strip 14, wire put check 15, the wire is put check 15 and is installed in software protecting crust 11 inside and be located the same axis on, top protecting layer 13 two are a set of and install atress main and feel body 12 between and, interior protecting strip 14 is located atress main and feels body 12 below and locate wire and put check 15 surface outside and put

Wherein, the software protective housing 11 includes supplementary drag piece 111, semi-static pivot 112, semi-arc push rod 113, extrusion rotation axis 114, promotes auxiliary wheel 115, seesaw wheel 116, seesaw pole 117, slope pulling pole 118, extension atress pole 119, linking axle 1110, semi-static pivot 112 runs through in supplementary drag piece 111 is inside and is located the centre, top protective layer 13 laminates in supplementary drag piece 111 and keeps away from the one end surface of semi-static pivot 112, semi-arc push rod 113 is two and runs through extrusion rotation axis 114 between for a set of and, it installs inside atress main sensing body 12 both ends to promote auxiliary wheel 115, it has seesaw wheel 116 to run through between two for a set of and for tilting pole 117, the one end that seesaw wheel 116 was kept away from to seesaw pole 117 is installed linking axle 1110, extension atress pole 119 and slope pulling pole 118 hinged joint, atress main sensing body 12 is two semi-convexes higher, the middle of the stress main sensing body 12 is used for better pushing and extruding the rotating shaft 114, the two ends of the stress main sensing body are protruded to assist the semi-arc push rod 113 to slide out along an arc, the semi-static rotating shaft 112 is fixed when no external force exists, but is driven when a slight external force exists, the semi-static rotating shaft is used for assisting the auxiliary dragging block 111 to drive the top protection layer 13 to better abut against the inner surface of the soft protection shell 11, external force is borne by the semi-static rotating shaft 112 in an expanding and thickening mode, when the tilting rod 117 moves along the radian of the tilting rod 117, the extension stress rod 119 is pulled to drive the inner protection strip 14 to move inwards along the moving track of the inner protection strip, and the rotating shaft between the two is used for assisting the better lead of the inner protection strip 14 to be attached to the outer surface of the placing grid 15.

The stressed main sensing body 12 comprises a stressed outer body 12a, a fixed central shaft 12b and an auxiliary friction wheel 12C, wherein the fixed central shaft 12b is welded at the inner partial bottom end of the stressed outer body 12a, the fixed central shaft 12b penetrates through the inner part of the auxiliary friction wheel 12C and is positioned on the same axis, a groove at the bottom of the stressed outer body 12a is of a C-shaped structure, the auxiliary friction wheel 12C can assist an external object to be removed from the stressed outer body 12a to smoothly slide, and the auxiliary friction wheel 12C installed in the groove in the stressed outer body 12a does not hinder the original pushing effect of the stressed outer body 12a or hinder the auxiliary friction wheel 12C assisting the external object to push.

Wherein the extrusion rotation shaft 114 comprises a mounting groove 114a, a fixed block 114b, a threaded rod 114c, a return spring 114d, a threaded sleeve 114e and a fixed mounting body 114f, a return spring 114d is installed in the installation groove 114a, fixed installation bodies 114f are vertically welded at the left end and the right end of the return spring 114d, the threaded sleeve 114e is positioned inside the mounting groove 114a and on the same axis, the right end of the threaded rod 114c is welded with a fixed block 114b, the return spring 114d is combined with the two fixed mounting bodies 114f into an i-shaped structure, when the object outside the mounting groove 114a drives it to rotate, it will be engaged with the outer side of the threaded rod 114c, and the return spring 114d will press the two, so that an object outside the mounting slot 114a will be rotated along the threaded rod 114c by the return spring 114d and will spring back to its original position when it loses resistance.

The specific use mode and function of the embodiment are as follows:

in the invention, when the stress reinforcing wire sleeve 1 is stepped by external force, the external stepping force extrudes the stress main sensing body 12, so that the middle part of the stress main sensing body 12 pushes the extrusion rotating shaft 114 to move inwards along, the half-arc push rod 113 arranged on the outer surface of the extrusion rotating shaft 114 moves through the arc of the half-arc push rod 113 per se, the half-arc push rod 113 drags the installation groove 114a together when moving, so as to be sleeved on the outer surface of the threaded rod 114c in a rotating way, the auxiliary friction wheel 12c assists in moving the extrusion rotating shaft, the auxiliary dragging block 111 and the top protection layer 13 are pushed to the inner part of the soft protection shell 11, the external stress area and the stress are thickened and expanded, the wire placing grid 15 which is difficult to extrude to the inner part is difficult to extrude, when the extrusion rotating shaft 114 is still extruded inwards under the external force, the tilting wheel 116 is pushed to move to a certain distance, by tilting rod 117 toward one end tilting along its own arc for slope pull rod 118 toward one side pulling extension atress pole 119, assist its interior foxtail 14 to attach and put check 15 shell at the wire and protect, prevent that external power is too big, put the inside wire of check 15 and cause the damage to the wire.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (1)

1. The utility model provides a building site atress adds protects recycles wire device, its structure includes that the atress consolidates wire cover (1), insulating casing (2), links up port (3), main shaft core (4), atress consolidates wire cover (1) right-hand member and runs through inside insulating casing (2) left end, link up port (3) and install in insulating casing (2) inside and be located the same axle center, main shaft core (4) run through in insulating casing (2) inside with the atress consolidate wire cover (1) and be connected its characterized in that:

the stress reinforcement wire sleeve (1) comprises a soft protective shell (11), stress main sensing bodies (12), top protective layers (13), inner protective strips (14) and wire placing grids (15), wherein the wire placing grids (15) are arranged in the soft protective shell (11) and are positioned on the same axis, the two top protective layers (13) are in a group, the stress main sensing bodies (12) are arranged between the two top protective layers, and the inner protective strips (14) are positioned below the stress main sensing bodies (12) and are arranged on the outer surfaces of the wire placing grids (15);

the soft protective shell (11) comprises an auxiliary dragging block (111), a semi-static rotating shaft (112), a semi-arc push rod (113), an extrusion rotating shaft (114), a pushing auxiliary wheel (115), a tilting wheel (116), a tilting rod (117), an inclined pulling rod (118), an extension stress rod (119) and a linking shaft (1110), wherein the semi-static rotating shaft (112) penetrates through the inner part of the auxiliary dragging block (111) and is positioned in the middle of the center, the top protective layer (13) is attached to one end surface of the auxiliary dragging block (111) far away from the semi-static rotating shaft (112), the two semi-arc push rods (113) are in a group, the extrusion rotating shaft (114) penetrates through the two semi-arc push rods, the pushing auxiliary wheel (115) is installed inside two ends of a stressed main sensing body (12), the two tilting rods (117) are in a group, a tilting wheel (116) penetrates through the two tilting rods, and the one end of the tilting rod (117) far away from the tilting wheel (116), the extension stress rod (119) is hinged with the inclined pulling rod (118), when the tilting rod (117) moves along the radian of the tilting rod, the extension stress rod (119) is pulled to drive the inner protection strip (14) to move inwards along the motion track of the inner protection strip, and a rotating shaft between the extension stress rod and the tilting rod is used for assisting the inner protection strip (14) to be better attached to the outer surface of the wire placing grid (15);

the stress main sensing body (12) comprises a stress outer body (12a), a fixed central shaft (12b) and an auxiliary friction wheel (12c), the fixed central shaft (12b) is welded at the inner partial bottom end of the stress outer body (12a), and the fixed central shaft (12b) penetrates through the inner part of the auxiliary friction wheel (12c) and is positioned on the same axis;

extrusion rotation axis (114) include mounting groove (114a), fixed block (114b), threaded rod (114c), return spring (114d), thread bush (114e), the fixed mounting body (114f), mounting groove (114a) internally mounted has return spring (114d), return spring (114d) is controlled both ends vertical welding and is had the fixed mounting body (114f), thread bush (114e) are located mounting groove (114a) inside and are located the same axle center, threaded rod (114c) right-hand member welding has fixed block (114 b).

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