CN111593943A - Protective fence equipment for engineering - Google Patents

Abstract

The invention relates to protective fence equipment, in particular to protective fence equipment for engineering, which comprises a fixed seat body mechanism, a sliding lifting mechanism, a front wheel mechanism and a rear wheel mechanism, wherein the equipment can be reinforced on the ground, can be lifted and moved, can be connected end to end between the equipment, is connected with the sliding lifting mechanism, is connected with the front wheel mechanism, is connected with the fixed seat body mechanism, is connected with the rear wheel mechanism, and is connected with the rear wheel mechanism.

Description

Protective fence equipment for engineering

Technical Field

The invention relates to protective fence equipment, in particular to protective fence equipment for engineering.

Background

The fence is often used in engineering construction, the conventional fence is inconvenient to move and arrange, but no good protective fence equipment for engineering exists in the market, so that the protective fence equipment for the engineering is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing protective fence equipment for engineering, wherein the equipment can be used for increasing weight and reinforcing on the ground, the equipment can be lifted and moved, and the equipment can be connected end to end.

In order to solve the technical problem, the invention relates to protective fence equipment, in particular to protective fence equipment for engineering, which comprises a fixed seat body mechanism; a sliding lifting mechanism; a front wheel mechanism; a rear wheel mechanism; the equipment can be strengthened subaerial weight gain, and equipment can rise, and equipment can remove, can receive end to end between equipment.

A fixed seat body mechanism; and a slide raising mechanism; a connecting, sliding raising mechanism; a front wheel mechanism; a front wheel mechanism; a fixed seat body mechanism; a rear wheel mechanism; a fixed seat body mechanism; a connecting, sliding raising mechanism; a rear wheel mechanism; and (4) connecting.

As a further optimization of the technical scheme, the invention relates to a protective fence device for engineering, which is characterized in that a base mechanism is fixed; comprises a power motor; a belt; and a transmission shaft; a reaction force propeller; the motor mounting plate; the mounting plate side plate; the mounting plate bottom plate; the limiting mounting plate a; the limiting sliding shaft; a limit spring; the limiting mounting plate b; a ball shaft; a ball axle seat; a power motor; a motor shaft and a belt on the frame; friction coupling, belt; and a drive shaft; a friction connection, a drive shaft; a reaction force propeller; connecting, namely mounting a motor plate; and a power motor; connecting and mounting the side plates; and a drive shaft; the bearing is connected with the mounting plate bottom plate; and a mounting plate side plate; connecting and limiting the mounting plate a; and a limit sliding shaft; connecting and limiting the sliding shaft; and a mounting plate base plate; the sliding connection is realized, and the spring is limited; the limiting sliding shaft is sleeved with the limiting sliding shaft; the upper part is limited on the mounting plate bottom plate; and a limit mounting plate b; a limiting mounting plate b; and a limit sliding shaft; a connection, a ball axle; and a limit sliding shaft; connecting with a ball axle seat; and a ball shaft; bearing connection and motor mounting plate; and a mounting plate side plate; and (4) connecting.

As a further optimization of the technical scheme, the invention relates to a protective fence device for engineering, which comprises a sliding lifting mechanism; comprises a sliding power motor; a sliding motor shaft; a transmission belt a; the sliding transmission shaft a; a gear a; a gear b; a gear c; the sliding transmission shaft b; a transmission belt b; a sliding transmission shaft c; a gear d; the sliding motor mounting plate; and a sliding block; the transmission shaft mounting plate a; the transmission shaft mounting plate b; a sliding fixing plate; a sliding mounting plate bottom plate; a sliding power motor; and a sliding motor shaft; connecting, sliding the motor shaft; and a transmission belt a; friction coupling, drive belt a; and a sliding transmission shaft a; a friction connection, sliding the transmission shaft a; and a gear a; connection, gear a; and a slider; sliding connection, gear b; and a gear c; engaged, gear c; and a sliding transmission shaft b; connecting and sliding the transmission shaft b; and a transmission belt b; friction coupling, drive belt b; and a sliding transmission shaft c; a friction connection, sliding the drive shaft c; and a gear d; connection, gear d; and a slider; connecting and sliding the motor mounting plate; and a sliding power motor; connecting, sliding block; and a sliding fixing plate; a sliding connection, a transmission shaft mounting plate a; and a sliding transmission shaft a; bearing connection, transmission shaft mounting plate b; and a sliding transmission shaft b; bearing connection, sliding fixing plate; mounting plate with sliding motor; connecting, sliding the mounting plate bottom plate; and a sliding fixing plate; connecting and sliding the transmission shaft c; a transmission shaft mounting plate a; bearing connection, transmission shaft mounting plate a; and a sliding fixing plate; connecting and driving shaft mounting plates b; and a sliding fixing plate; and (4) connecting.

As further optimization of the technical scheme, the protective fence equipment for the engineering is characterized in that the front wheel mechanism is arranged on the front wheel mechanism; comprises a supporting power motor; the supporting motor shaft; supporting the transmission belt; the supporting transmission shaft; the supporting connecting plate a; the supporting connecting plate b; the supporting connecting plate c; a universal wheel mechanism; the support connecting plate d; and a handle; the supporting connecting plate e; the supporting connecting plate f; a strong magnetic plate; supporting the power motor; and a supporting motor shaft; connecting and supporting the motor shaft; and a support drive belt; a friction connection supporting the drive belt; and a support drive shaft; the friction connection supports the transmission shaft; and a support connection plate a; the bearing is connected with the connecting plate a in a supporting mode; and a support connection plate e; connecting and supporting the connecting plate b; and a support drive shaft; connecting and supporting the connecting plate c; and a support drive shaft; bearing connection and universal wheel mechanism; and a support drive shaft; connecting and supporting the connecting plate d; and a handle; connecting and supporting the connecting plate e; and a support connection plate c; connecting and supporting the connecting plate f; and a support connection plate f; connecting, namely, a strong magnetic plate; and a support connection plate f; connecting and supporting the connecting plate d; and a support connection plate e; connecting; a universal wheel mechanism; comprises a straight shaft sleeve; the connecting straight shaft; the connecting crankshaft; a front wheel bearing fork; a front wheel bearing column; a front wheel; a straight shaft sleeve; and a connecting straight shaft; the bearing is connected with the straight shaft; and a connecting crankshaft; a connection, connecting the crankshaft; a front wheel bearing fork; a front wheel bearing fork; and a front wheel bearing post; bearing connection, front wheel bearing column; and a front wheel; the bearing is connected with the straight shaft; and a support drive shaft; and (4) connecting.

As further optimization of the technical scheme, the protective fence equipment for the engineering is characterized in that the rear wheel mechanism is arranged on the rear wheel mechanism; comprises a rotary power motor; a rotary transmission belt a; the rotating transmission shaft a; a rotary gear a; the rotary connecting plate a; a rotating gear b; the rotating transmission shaft b; a rotary bearing block a; a rotary bearing block b; the rotary connecting plate b; the rotating connecting plate c; the rotating connecting plate d; the rotating connecting plate e; the reset shaft is connected in a rotating manner; the rotating connecting plate f; a rotary return spring; connecting the flexible board a; the rotary connecting plate g; a strong magnetic plate; a rotary transmission belt b; rotating the power motor; an upper motor shaft and a rotating transmission belt a; a friction connection, rotating the drive belt a; and a rotary transmission shaft a; friction connection, rotating the transmission shaft a; and a rotary gear a; connecting, rotating gear a; and a rotary gear b; engaged, rotating the web a; and a rotary transmission shaft a; bearing connection, rotating gear b; and a rotary transmission shaft b; connecting and rotating a transmission shaft b; and a rotary bearing block a; connecting, rotating the bearing block a; and a rotary bearing block b; connecting and rotating the bearing block b; and a rotary connecting plate b; connecting and rotating the connecting plate c; and a rotary connecting plate d; connecting and rotating the connecting plate d; and a rotary connecting plate f; connecting and rotating the connecting plate e; and a rotary power motor; the connection is rotationally connected with the reset shaft; and a rotary connecting plate f; the connecting plate f is connected in a sliding way and rotated; and connecting the soft board a; a sliding connection, rotating the return spring; the sleeve is rotatably connected with a reset shaft; the upper part is limited on the rotating connecting plate f; and a rotary connecting plate g; connecting the soft board a; and a rotary connecting plate d; the connecting plate g is connected in a sliding mode and rotated; and connecting the soft board a; connecting, namely, a strong magnetic plate; and a rotary connecting plate g; connecting and rotating a transmission belt b; and a rotary power motor; the motor shaft on the transmission shaft b is in friction connection and rotates the transmission shaft b; a rotation transmission belt b; a friction connection, rotating the bearing block a; and a rotary connecting plate d; connecting and rotating the connecting plate c; and a mounting plate side plate; connecting and rotating the connecting plate e; and a mounting plate side plate; connecting the soft board a; and a mounting plate side plate; and (4) connecting.

As a further optimization of the technical scheme, the protective fence equipment for engineering is characterized in that the rotary connecting plate d is arranged on the base; and a rotary connecting plate f; and connecting the soft board a; the material is high elastic rubber which can generate elastic deformation.

The protective fence equipment for engineering has the beneficial effects that:

according to the protective fence equipment for the engineering, the equipment can be used for increasing weight and reinforcing on the ground, the equipment can be lifted and moved, and the equipment can be connected end to end.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a first structural schematic diagram of a protective fence device for engineering according to the present invention.

Fig. 2 is a schematic structural diagram of a protective fence apparatus for engineering according to the present invention.

Fig. 3 is a first structural schematic diagram of a fixing seat mechanism 1 of a protective fence device for engineering according to the present invention.

Fig. 4 is a second structural schematic diagram of the fixed seat mechanism 1 of the protective fence device for engineering of the present invention.

Fig. 5 is a first structural schematic diagram of the sliding lifting mechanism 2 of the protective fence device for engineering of the invention.

Fig. 6 is a second structural schematic diagram of the sliding lifting mechanism 2 of the protective fence device for engineering of the present invention.

Fig. 7 is a third schematic structural diagram of the sliding lifting mechanism 2 of the protective fence device for engineering of the invention.

Fig. 8 is a first structural schematic diagram of the front wheel mechanism 3 of the protective fence device for engineering of the invention.

Fig. 9 is a second schematic structural diagram of the front wheel mechanism 3 of the protective fence device for engineering of the present invention.

Fig. 10 is a schematic structural diagram of the universal wheel mechanism 3-8 of the protective fence device for engineering of the invention.

Fig. 11 is a first structural schematic diagram of the rear wheel mechanism 4 of the protective fence device for engineering of the invention.

Fig. 12 is a second schematic structural diagram of the rear wheel mechanism 4 of the protective fence device for engineering of the present invention.

Fig. 13 is a schematic structural view of the connecting soft board a4-17 of the protective fence device for engineering of the invention.

In the figure: a fixed seat mechanism 1; a power motor 1-1; 1-2 of a belt; 1-3 of a transmission shaft; 1-4 of a reaction force propeller; 1-5 of a motor mounting plate; mounting side plates 1-6; mounting plate bottom plates 1-7; a limiting mounting plate a 1-8; limiting sliding shafts 1-9; 1-10 parts of a limiting spring; a limit mounting plate b 1-11; 1-12 parts of a ball shaft; 1-13 parts of a ball shaft seat; a slide raising mechanism 2; a sliding power motor 2-1; a sliding motor shaft 2-2; a transmission belt a 2-3; a sliding transmission shaft a 2-4; gear a 2-5; gear b 2-6; gear c 2-7; a sliding transmission shaft b 2-8; a transmission belt b 2-9; a sliding transmission shaft c 2-10; gear d 2-11; a sliding motor mounting plate 2-12; 2-13 of a sliding block; a drive shaft mounting plate a 2-14; a transmission shaft mounting plate b 2-15; a sliding fixing plate 2-16; sliding mounting plate bottom plates 2-17; a front wheel mechanism 3; supporting a power motor 3-1; supporting the motor shaft 3-2; supporting a transmission belt 3-3; supporting a transmission shaft 3-4; supporting connecting plate a 3-5; supporting connecting plate b 3-6; support connection board c 3-7; 3-8 parts of universal wheel mechanism; 3-8-1 of a straight shaft sleeve; connecting the straight shaft 3-8-2; connecting a crankshaft 3-8-3; 3-8-4 parts of front and rear wheel bearing forks; front and rear wheel bearing columns 3-8-5; 3-8-6 parts of front and rear wheels; supporting connecting plate d 3-9; 3-10 parts of a handle; supporting connecting plate e 3-11; support web f 3-12; 3-13 of a ferromagnetic plate; a rear wheel mechanism 4; a rotary power motor 4-1; a rotary driving belt a 4-2; a rotary transmission shaft a 4-3; rotary gear a 4-4; a rotary connecting plate a 4-5; rotary gear b 4-6; a rotary transmission shaft b 4-7; a rotary bearing block a 4-8; a swivel bearing block b 4-9; a rotary connecting plate b 4-10; a rotary connecting plate c 4-11; a rotary connecting plate d 4-12; a rotary connecting plate e 4-13; the reset shaft 4-14 is connected in a rotating way; a rotary connecting plate f 4-15; rotating the return spring 4-16; connecting the soft boards a 4-17; rotating connecting plates g 4-18; 4-19 of a strong magnetic plate; rotating the drive belt b 4-20.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, and fig. 13, and the present invention relates to a protective fence apparatus, and more specifically, to a protective fence apparatus for engineering, which includes a fixed seat mechanism 1, a sliding raising mechanism 2, a front wheel mechanism 3, and a rear wheel mechanism 4, and the apparatus can be reinforced on the ground, can be raised, can be moved, and can be connected end to end between apparatuses.

The fixed seat body mechanism 1 is connected with the sliding lifting mechanism 2, the sliding lifting mechanism 2 is connected with the front wheel mechanism 3, the front wheel mechanism 3 is connected with the fixed seat body mechanism 1, the rear wheel mechanism 4 is connected with the fixed seat body mechanism 1, and the sliding lifting mechanism 2 is connected with the rear wheel mechanism 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and the embodiment further describes the embodiment, where the fixed seat mechanism 1 includes a power motor 1-1, a belt 1-2, a transmission shaft 1-3, a reaction force propeller 1-4, a motor mounting plate 1-5, a mounting plate side plate 1-6, a mounting plate bottom plate 1-7, a limit mounting plate a1-8, a limit sliding shaft 1-9, a limit spring 1-10, a limit mounting plate b1-11, a ball shaft 1-12, and a ball shaft seat 1-13, a motor shaft on the power motor 1-1 is frictionally connected with the belt 1-2, and the belt 1-3 is frictionally connected with the transmission shaft 1-3, a transmission shaft 1-3 is connected with a reaction force propeller 1-4, a motor mounting plate 1-5 is connected with a power motor 1-1, a mounting plate side plate 1-6 is connected with a transmission shaft 1-3 bearing, a mounting plate bottom plate 1-7 is connected with a mounting plate side plate 1-6, a limit mounting plate a1-8 is connected with a limit sliding shaft 1-9, a limit sliding shaft 1-9 is connected with a mounting plate bottom plate 1-7 in a sliding way, a limit spring 1-10 is sleeved on the limit sliding shaft 1-9 and limited on the mounting plate bottom plate 1-7 and a limit mounting plate b1-11, a limit mounting plate b1-11 is connected with a limit sliding shaft 1-9, a ball shaft 1-12 is connected with a limit sliding shaft 1-9, a ball shaft seat 1-13 is connected with a ball shaft 1-12 bearing, the motor mounting plate 1-5 is connected with the mounting plate side plate 1-6, the equipment can be reinforced on the ground, the power motor 1-1 rotates through the belt 1-2 to drive the two transmission shafts 1-3 to rotate, the transmission shafts 1-3 rotate to drive the reaction force propellers 1-4 to rotate, when the reaction force propellers 1-4 rotate anticlockwise, the reaction force propellers 1-4 can generate downward compressed air, the reaction force propellers 1-4 act on the mounting plate bottom plate 1-7 to enable the mounting plate bottom plate 1-7 to move downwards, when the mounting plate bottom plate 1-7 moves downwards, the limiting springs 1-10 are pressed through the limiting sliding shafts 1-9 to enable the limiting springs 1-10 to bear force, the force of the limiting springs 1-10 is transferred to the limiting mounting plate b1-11, the limiting mounting plate b1-11 continuously transmits the downward pressure to the ball shafts 1-12 and the ball shaft seats 1-13 under the action of the limiting sliding shafts 1-9, so that the weight of the whole equipment is increased and reinforced.

The third concrete implementation mode:

referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, the present embodiment further illustrates the present embodiment, where the sliding raising mechanism 2 includes a sliding power motor 2-1, a sliding motor shaft 2-2, a transmission belt a2-3, a sliding transmission shaft a2-4, a gear a2-5, a gear b2-6, a gear c2-7, a sliding transmission shaft b2-8, a transmission belt b2-9, a sliding transmission shaft c2-10, a gear d2-11, a sliding motor mounting plate 2-12, a sliding block 2-13, a transmission shaft mounting plate a2-14, a transmission shaft mounting plate b2-15, a sliding fixing plate 2-16, a sliding mounting plate bottom plate 2-17, a sliding power motor 2-1 is connected with a sliding motor shaft 2-2, the sliding motor shaft 2-2 is in frictional connection with a transmission belt a2-3, the transmission belt a2-3 is in frictional connection with a sliding transmission shaft a2-4, the sliding transmission shaft a2-4 is connected with a gear a2-5, the gear a2-5 is in sliding connection with a sliding block 2-13, the gear b2-6 is meshed with a gear c2-7, the gear c2-7 is connected with a sliding transmission shaft b2-8, the sliding transmission shaft b2-8 is in frictional connection with a transmission belt b2-9, the transmission belt b2-9 is in frictional connection with a sliding transmission shaft c2-10, the sliding transmission shaft c2-10 is connected with a gear d2-11, the gear d2-11 is connected with a sliding block 2-13, a sliding motor mounting plate 2-12 is connected with the sliding power motor 2-1, sliding blocks 2-13 are in sliding connection with sliding fixing plates 2-16, transmission shaft mounting plates a2-14 are in bearing connection with sliding transmission shafts a2-4, transmission shaft mounting plates b2-15 are in bearing connection with sliding transmission shafts b2-8, sliding fixing plates 2-16 are in bearing connection with sliding motor mounting plates 2-12, sliding mounting plate bottom plates 2-17 are in connection with sliding fixing plates 2-16, sliding transmission shafts c2-10 are in bearing connection with transmission shaft mounting plates a2-14, transmission shaft mounting plates a2-14 are in connection with sliding fixing plates 2-16, transmission shaft mounting plates b2-15 are in connection with sliding fixing plates 2-16, equipment can be lifted, sliding power motors 2-1 rotate to drive sliding motor shafts 2-2 to rotate, sliding motor shafts 2-2 rotate to drive sliding transmission shafts a2 through transmission belts a2-3 4, the sliding transmission shaft a2-4 rotates to drive the gear a2-5 to rotate, the sliding motor shaft 2-2 simultaneously drives the gear b2-6 to rotate when rotating, the gear b2-6 rotates to drive the sliding transmission shaft b2-8 to rotate reversely through the gear c2-7, the sliding transmission shaft b2-8 rotates reversely to drive the sliding transmission shaft c2-10 to rotate through the transmission belt b2-9, the sliding transmission shaft c2-10 rotates to drive the gear d2-11 to rotate, the gear a2-5 and the gear d2-11 simultaneously rotate and synchronously drive the sliding blocks 2-13 at two sides to slide in the grooves on the sliding fixing plates 2-16, because the gear a2-5 and the gear d2-11 rotate positively and reversely, the sliding blocks 2-13 at two sides can synchronously move upwards or downwards, when the two side sliding blocks 2-13 slide upwards, the equipment is lifted.

The fourth concrete implementation mode:

referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, the present embodiment further illustrates an embodiment in which the front wheel mechanism 3 includes a support power motor 3-1, a support motor shaft 3-2, a support transmission belt 3-3, a support transmission shaft 3-4, a support connection plate a3-5, a support connection plate b3-6, a support connection plate c3-7, a universal wheel mechanism 3-8, a support connection plate d3-9, a handle 3-10, a support connection plate e3-11, a support connection plate f3-12, a strong magnetic plate 3-13, the support power motor 3-1 is connected to the support motor shaft 3-2, the support motor shaft 3-2 is frictionally connected to the support transmission belt 3-3, the support driving belt 3-3 is in friction connection with the support driving shaft 3-4, the support driving shaft 3-4 is in bearing connection with a support connecting plate a3-5, the support connecting plate a3-5 is connected with a support connecting plate e3-11, the support connecting plate b3-6 is connected with the support driving shaft 3-4, the support connecting plate c3-7 is in bearing connection with the support driving shaft 3-4, the universal wheel mechanism 3-8 is connected with the support driving shaft 3-4, the support connecting plate d3-9 is connected with the handle 3-10, the support connecting plate e3-11 is connected with a support connecting plate c3-7, the support connecting plate f3-12 is connected with a support connecting plate f3-12, the strong magnetic plate 3-13 is connected with a support connecting plate f3-12, and the support connecting plate d3-9 is connected with a support connecting plate e 36; the universal wheel mechanism 3-8 comprises a straight shaft sleeve 3-8-1, a connecting straight shaft 3-8-2, a connecting crankshaft 3-8-3, a front and rear wheel bearing fork 3-8-4, a front and rear wheel bearing column 3-8-5 and a front and rear wheel bearing column 3-8-5, wherein the straight shaft sleeve 3-8-1 is connected with the connecting straight shaft 3-8-2 through a bearing, the connecting straight shaft 3-8-2 is connected with the connecting crankshaft 3-8-3, the connecting crankshaft 3-8-3 is connected with the front and rear wheel bearing fork 3-8-4, the front and rear wheel bearing fork 3-8-4 is connected with the front and rear wheel bearing column 3-8-5 through a bearing, the front and rear wheel bearing column 3-8-5 is connected with the front and rear wheel bearing column 3-8-5 through a bearing, the connecting straight shaft 3-8-2 is connected with the supporting transmission shaft 3-4.

The fifth concrete implementation mode:

referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, the present embodiment will be further described, wherein the rear wheel mechanism 4 includes a rotary power motor 4-1, a rotary transmission belt a4-2, a rotary transmission shaft a4-3, a rotary gear a4-4, a rotary connection plate a4-5, a rotary gear b4-6, a rotary transmission shaft b4-7, a rotary bearing block a4-8, a rotary bearing block b4-9, a rotary connection plate b4-10, a rotary connection plate c4-11, a rotary connection plate d4-12, a rotary connection plate e4-13, a rotary connection reset shaft 4-14, a rotary connection plate f4-15, a rotary reset spring 4-16, a rotary reset spring c4-11, a rotary connection plate d4-12, a rotary connection plate e4-13, a rotary reset shaft 4-14, a rotary connection plate f 35, A soft connecting plate a4-17, a rotary connecting plate g4-18, a strong magnetic plate 4-19 and a rotary transmission belt b4-20, wherein the motor shaft of the rotary power motor 4-1 is in friction connection with the rotary transmission belt a4-2, the rotary transmission belt a4-2 is in friction connection with a rotary transmission shaft a4-3, the rotary transmission shaft a4-3 is connected with a rotary gear a4-4, the rotary gear a4-4 is meshed with a rotary gear b4-6, the rotary connecting plate a4-5 is in bearing connection with a4-3, the rotary gear b4-6 is connected with a rotary transmission shaft b4-7, the rotary transmission shaft b4-7 is connected with a rotary bearing block a4-8, the rotary bearing block a4-8 is connected with a rotary bearing block b4-9, the rotary bearing block b4-9 is connected with a rotary connecting plate 539b 4-10, the rotary connecting plate c4-11 is connected with a rotary connecting plate d4-12, the rotary connecting plate d4-12 is connected with a rotary connecting plate f4-15, the rotary connecting plate e4-13 is connected with a rotary power motor 4-1, the rotary connecting reset shaft 4-14 is in sliding connection with the rotary connecting plate f4-15, the rotary connecting plate f4-15 is in sliding connection with a connecting soft plate a4-17, a rotary reset spring 4-16 is sleeved on the rotary connecting reset shaft 4-14 and limited on the rotary connecting plate f4-15 and the rotary connecting plate g4-18, the connecting soft plate a4-17 is in sliding connection with the rotary connecting plate d4-12, the rotary connecting plate g4-18 is connected with the connecting soft plate a4-17, a strong magnetic plate 4-19 is connected with the rotary connecting plate g4-18, a rotary transmission belt b4-20 is in friction connection with a motor shaft on the rotary power motor 4-1, the rotary transmission shaft b4-7 is in frictional connection with a rotary transmission belt b4-20, the rotary bearing block a4-8 is connected with a rotary connecting plate d4-12, the rotary connecting plate c4-11 is connected with a mounting plate side plate 1-6, the rotary connecting plate e4-13 is connected with the mounting plate side plate 1-6, the connecting soft plate a4-17 is connected with the mounting plate side plate 1-6, the device can move, the support power motor 3-1 rotates to drive the support motor shaft 3-2 to rotate, the support motor shaft 3-2 rotates to drive the support transmission shaft 3-4 to rotate through the support transmission belt 3-3, the support transmission shaft 3-4 rotates to drive the support connecting plate c3-7 to move upwards, the support transmission shaft 3-4 moves downwards to drive the connecting straight shaft 3-8-2 to move downwards, the connecting straight shaft 3-8-2 drives the connecting crankshaft 3-8-3 to move downwards, the connecting crankshaft 3-8-3 drives the front and rear wheel bearing forks 3-8-4 to move downwards, the front and rear wheel bearing forks 3-8-4 drive the front and rear wheel bearing columns 3-8-5 to move downwards, the front and rear wheel bearing columns 3-8-5 drive the front and rear wheel bearing columns 3-8-5 to move downwards, the supporting connecting plate b3-6 is also driven to move when the supporting transmission shaft 3-4 moves, the supporting connecting plate b3-6 moves until the front wheel is in contact with the supporting connecting plate a3-5 to reach a limit position, the rotating power motor 4-1 rotates, the rotating power motor 4-1 drives the rotating transmission shaft a4-3 to rotate through the motor shaft and the rotating transmission belt a4-2, the rotary transmission shaft a4-3 rotates to drive the rotary gear b4-6 to rotate through the rotary gear a4-4, the rotary gear b4-6 rotates to drive the rotary transmission shaft b4-7 to rotate, the rotary transmission shaft b4-7 rotates to drive the rotary bearing block b4-9 at one side to rotate by taking the center of the rotary bearing block a4-8 as a circle center, the rotary bearing block b4-9 rotates to drive the rotary connecting plate b4-10 to rotate, the rotary connecting plate b4-10 rotates to reach a limit when the rotary connecting plate b4-10 rotates clockwise and contacts a plate in the middle of the rotary bearing block b4-9, the rotary connecting plate b4-10 also drives the straight shaft sleeve 3-8-1 when rotating, the straight shaft sleeve 3-8-1 moves to drive the connecting straight shaft 3-8-2, the connecting straight shaft 3-8-2 moves to drive the connecting crankshaft 3-8-3 to move, the connecting crank shaft 3-8-3 moves to drive the front wheel bearing fork 3-8-4 to rotate, the front wheel bearing fork 3-8-4 moves to drive the front wheel bearing column 3-8-5 to move, the front wheel bearing column 3-8-5 moves to drive the front wheel bearing column 3-8-5 to rotate, the front wheel bearing column 3-8-5 gradually supports the equipment when rotating, at the moment, the handle 3-10 is pulled, the handle 3-10 drives the supporting connecting plate d3-9 to move, the supporting connecting plate d3-9 drives the whole equipment to move, and when the equipment moves, due to the physical characteristics of the connecting crank shaft 3-8-3, the handle 3-10 can be pulled to move smoothly in the front, back, left and right directions.

The sixth specific implementation mode:

referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, this embodiment further describes an embodiment, the rotation connection plate d4-12, the rotation connection plate f4-15 and the connection soft plate a4-17 are made of high elastic rubber, and can generate elastic deformation, the device and the device can be connected end to end, the device and the device are opposite, because of the magnetic force of the strong magnetic plates 3-13 and the strong magnetic plates 4-19, the device and the device are mutually adsorbed, when one device is rotated, the rotation connection plates g4-18 follow the rotation, when the rotation connection plate g4-18 rotates, the connection soft plate a4-17 is driven to move, when the connection soft plate a4-17 moves, the rotation connection plate f 4-3515 moves, the rotation connection plate f4-15 moves to one end of the connection soft plate a4-17 slot to reach the limit position of the device, the flexible connecting boards a4-17 can be bent by the physical characteristics of the flexible connecting boards a4-17, namely, the device and the device can rotate at the position of the flexible connecting boards a4-17 when being connected.

The working principle of the device is as follows: the equipment can be reinforced by increasing weight on the ground, the power motor 1-1 rotates to drive the two transmission shafts 1-3 to rotate through the belt 1-2, the transmission shafts 1-3 rotate to drive the reaction force propellers 1-4 to rotate, when the reaction force propellers 1-4 rotate anticlockwise, the reaction force propellers 1-4 can generate downward compressed air, the reaction force propellers 1-4 act on the installation plate bottom plates 1-7 to enable the installation plate bottom plates 1-7 to move downwards, the installation plate bottom plates 1-7 press the limiting springs 1-10 through the limiting sliding shafts 1-9 when moving downwards to enable the limiting springs 1-10 to bear force, the bearing force of the limiting springs 1-10 is transmitted to the limiting installation plates b1-11, and the limiting installation plates b1-11 continuously transmit the downward force to the ball shafts 1-12 under the action of the limiting sliding shafts 1-9 And a ball axle seat 1-13, so that the weight of the whole equipment is increased and strengthened, the equipment can be lifted, a sliding power motor 2-1 rotates, the sliding power motor 2-1 rotates to drive a sliding motor shaft 2-2 to rotate, the sliding motor shaft 2-2 rotates to drive a sliding transmission shaft a2-4 to rotate through a transmission belt a2-3, the sliding transmission shaft a2-4 rotates to drive a gear a2-5 to rotate, the sliding motor shaft 2-2 rotates while driving a gear b2-6 to rotate, the gear b2-6 rotates to drive a sliding transmission shaft b2-8 to rotate reversely through a gear c2-7, the sliding transmission shaft b2-8 rotates reversely to drive a sliding transmission shaft c2-10 to rotate through a transmission belt b2-9, and the sliding transmission shaft c2-10 rotates to drive a gear d2-11 to rotate, the gear a2-5 and the gear d2-11 rotate simultaneously and synchronously to drive the sliding blocks 2-13 at two sides to slide in the grooves on the sliding fixing plates 2-16, because the gear a2-5 and the gear d2-11 rotate in a forward direction and a reverse direction, the sliding blocks 2-13 at two sides can move upwards or downwards synchronously, when the sliding blocks 2-13 at two sides slide upwards, the equipment can move, the supporting power motor 3-1 rotates to drive the supporting motor shaft 3-2 to rotate, the supporting motor shaft 3-2 rotates to drive the supporting transmission shaft 3-4 to rotate through the supporting transmission belt 3-3, the supporting transmission shaft 3-4 rotates to drive the supporting connection plate c3-7 to move upwards, the supporting transmission shaft 3-4 moves downwards to drive the connecting straight shaft 3-8-2 to move downwards, the connecting straight shaft 3-8-2 drives the connecting crankshaft 3-8-3 to move downwards, the connecting crankshaft 3-8-3 drives the front and rear wheel bearing forks 3-8-4 to move downwards, the front and rear wheel bearing forks 3-8-4 drive the front and rear wheel bearing columns 3-8-5 to move downwards, the front and rear wheel bearing columns 3-8-5 drive the front and rear wheel bearing columns 3-8-5 to move downwards, the supporting connecting plate b3-6 is also driven to move when the supporting transmission shaft 3-4 moves, the supporting connecting plate b3-6 moves until the front wheel is in contact with the supporting connecting plate a3-5 to reach a limit position, the rotating power motor 4-1 rotates, the rotating power motor 4-1 drives the rotating transmission shaft a4-3 to rotate through the motor shaft and the rotating transmission belt a4-2, the rotary transmission shaft a4-3 rotates to drive the rotary gear b4-6 to rotate through the rotary gear a4-4, the rotary gear b4-6 rotates to drive the rotary transmission shaft b4-7 to rotate, the rotary transmission shaft b4-7 rotates to drive the rotary bearing block b4-9 at one side to rotate by taking the center of the rotary bearing block a4-8 as a circle center, the rotary bearing block b4-9 rotates to drive the rotary connecting plate b4-10 to rotate, the rotary connecting plate b4-10 rotates to reach a limit when the rotary connecting plate b4-10 rotates clockwise and contacts a plate in the middle of the rotary bearing block b4-9, the rotary connecting plate b4-10 also drives the straight shaft sleeve 3-8-1 when rotating, the straight shaft sleeve 3-8-1 moves to drive the connecting straight shaft 3-8-2, the connecting straight shaft 3-8-2 moves to drive the connecting crankshaft 3-8-3 to move, the connecting crank shaft 3-8-3 moves to drive the front and rear wheel bearing forks 3-8-4 to rotate, the front and rear wheel bearing forks 3-8-4 move to drive the front and rear wheel bearing columns 3-8-5 to move, the front and rear wheel bearing columns 3-8-5 move to drive the front and rear wheel bearing columns 3-8-5 to rotate, the equipment is gradually supported when the front and rear wheel bearing columns 3-8-5 rotate, the handle 3-10 is pulled at the moment, the handle 3-10 drives the supporting connecting plate d3-9 to move, the supporting connecting plate d3-9 drives the whole equipment to move, the handle 3-10 is pulled to move towards the front, the back, the left and the right directions due to the physical characteristic of the connecting crank shaft 3-8-3 when the equipment moves, the equipment can move smoothly, and the equipment can be connected end to end, the equipment and the equipment are in a tail-ending opposite state, the equipment and the equipment are mutually adsorbed due to the magnetic force of the strong magnetic plates 3-13 and the strong magnetic plates 4-19, when one equipment is rotated, the rotating connecting plates g4-18 rotate along with the equipment, the rotating connecting plates g4-18 drive the connecting soft plates a4-17 to move when the rotating connecting plates g4-18 rotate, the rotating connecting plates f4-15 are driven to move when the connecting soft plates a4-17 move, the equipment reaches a limit position when the rotating connecting plates f4-15 move to one end of the connecting soft plates a4-17 groove, the bending can be realized through the self physical characteristics when the connecting soft plates a4-17 move, namely the equipment and the equipment can rotate at the connecting soft plates a4-17 position when being connected,

it is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (6)

1. The utility model provides an engineering is with protection rail equipment, includes fixing base mechanism (1), slip rising mechanism (2), front wheel mechanism (3), rear wheel mechanism (4), its characterized in that: the lifting mechanism is characterized in that the fixed seat body mechanism (1) is connected with the sliding lifting mechanism (2), the sliding lifting mechanism (2) is connected with the front wheel mechanism (3), the front wheel mechanism (3) is connected with the fixed seat body mechanism (1), the rear wheel mechanism (4) is connected with the fixed seat body mechanism (1), and the sliding lifting mechanism (2) is connected with the rear wheel mechanism (4).

2. The protective fence equipment for engineering as claimed in claim 1, wherein: the fixed seat body mechanism (1) comprises a power motor (1-1), a belt (1-2), a transmission shaft (1-3), a reaction force propeller (1-4), a motor mounting plate (1-5), a mounting plate side plate (1-6), a mounting plate bottom plate (1-7), a limiting mounting plate a (1-8), a limiting sliding shaft (1-9), a limiting spring (1-10), a limiting mounting plate b (1-11), a ball shaft (1-12) and a ball shaft seat (1-13), wherein a motor shaft on the power motor (1-1) is in friction connection with the belt (1-2), the belt (1-2) is in friction connection with the transmission shaft (1-3), and the transmission shaft (1-3) is connected with the reaction force propeller (1-4), the motor mounting plate (1-5) is connected with the power motor (1-1), the mounting plate side plate (1-6) is connected with the transmission shaft (1-3) through a bearing, the mounting plate bottom plate (1-7) is connected with the mounting plate side plate (1-6), the limiting mounting plate a (1-8) is connected with the limiting sliding shaft (1-9), the limiting sliding shaft (1-9) is connected with the mounting plate bottom plate (1-7) in a sliding manner, the limiting spring (1-10) is sleeved on the limiting sliding shaft (1-9) and limited on the mounting plate bottom plate (1-7) and the limiting mounting plate b (1-11), the limiting mounting plate b (1-11) is connected with the limiting sliding shaft (1-9), the ball shaft (1-12) is connected with the limiting sliding shaft (1-9), the ball shaft seat (1-13) is connected with the ball shaft (1-12) through a bearing, the motor mounting plate (1-5) is connected with the mounting plate side plate (1-6).

3. The protective fence equipment for engineering as claimed in claim 1, wherein: the sliding lifting mechanism (2) comprises a sliding power motor (2-1), a sliding motor shaft (2-2), a transmission belt a (2-3), a sliding transmission shaft a (2-4), a gear a (2-5), a gear b (2-6), a gear c (2-7), a sliding transmission shaft b (2-8), a transmission belt b (2-9), a sliding transmission shaft c (2-10), a gear d (2-11), a sliding motor mounting plate (2-12), a sliding block (2-13), a transmission shaft mounting plate a (2-14), a transmission shaft mounting plate b (2-15), a sliding fixing plate (2-16) and a sliding mounting plate bottom plate (2-17), wherein the sliding power motor (2-1) is connected with the sliding motor shaft (2-2), a sliding motor shaft (2-2) is in frictional connection with a transmission belt a (2-3), the transmission belt a (2-3) is in frictional connection with a sliding transmission shaft a (2-4), the sliding transmission shaft a (2-4) is connected with a gear a (2-5), the gear a (2-5) is in sliding connection with a sliding block (2-13), a gear b (2-6) is meshed with a gear c (2-7), the gear c (2-7) is connected with a sliding transmission shaft b (2-8), the sliding transmission shaft b (2-8) is in frictional connection with a transmission belt b (2-9), the transmission belt b (2-9) is in frictional connection with a sliding transmission shaft c (2-10), the sliding transmission shaft c (2-10) is connected with a gear d (2-11), the gear d (2-11) is connected with a sliding block (2-13), the sliding motor mounting plate (2-12) is connected with a sliding power motor (2-1), the sliding block (2-13) is connected with a sliding fixing plate (2-16) in a sliding mode, the transmission shaft mounting plate a (2-14) is connected with a sliding transmission shaft a (2-4) in a bearing mode, the transmission shaft mounting plate b (2-15) is connected with a sliding transmission shaft b (2-8) in a bearing mode, the sliding fixing plate (2-16) is connected with the sliding motor mounting plate (2-12), the sliding mounting plate bottom plate (2-17) is connected with the sliding fixing plate (2-16), the sliding transmission shaft c (2-10) is connected with the transmission shaft mounting plate a (2-14) in a bearing mode, the transmission shaft mounting plate a (2-14) is connected with the sliding fixing plate (2-16), and the transmission shaft mounting plate b (2-15) is connected with the sliding.

4. The protective fence equipment for engineering as claimed in claim 1, wherein: the front wheel mechanism (3) comprises a supporting power motor (3-1), a supporting motor shaft (3-2), a supporting transmission belt (3-3), a supporting transmission shaft (3-4), a supporting connection plate a (3-5), a supporting connection plate b (3-6), a supporting connection plate c (3-7), a universal wheel mechanism (3-8), a supporting connection plate d (3-9), a handle (3-10), a supporting connection plate e (3-11), a supporting connection plate f (3-12) and a strong magnetic plate (3-13), wherein the supporting power motor (3-1) is connected with the supporting motor shaft (3-2), the supporting motor shaft (3-2) is in friction connection with the supporting transmission belt (3-3), the supporting transmission belt (3-3) is in friction connection with the supporting transmission shaft (3-4), the support transmission shaft (3-4) is in bearing connection with a support connection plate a (3-5), the support connection plate a (3-5) is in bearing connection with a support connection plate e (3-11), the support connection plate b (3-6) is in bearing connection with the support transmission shaft (3-4), the support connection plate c (3-7) is in bearing connection with the support transmission shaft (3-4), the universal wheel mechanism (3-8) is in connection with the support transmission shaft (3-4), the support connection plate d (3-9) is in connection with the handle (3-10), the support connection plate e (3-11) is in connection with the support connection plate c (3-7), the support connection plate f (3-12) is in connection with a support connection plate f (3-12), and the strong magnetic plate (3-13) is in connection with the support connection plate f (3-12), the supporting connecting plate d (3-9) is connected with the supporting connecting plate e (3-11); the universal wheel mechanism (3-8) comprises a straight shaft sleeve (3-8-1), a connecting straight shaft (3-8-2), a connecting crankshaft (3-8-3), front and rear wheel bearing forks (3-8-4), front and rear wheel bearing columns (3-8-5) and front and rear wheels (3-8-6), wherein the straight shaft sleeve (3-8-1) is in bearing connection with the connecting straight shaft (3-8-2), the connecting straight shaft (3-8-2) is in bearing connection with the connecting crankshaft (3-8-3), the connecting crankshaft (3-8-3) is in bearing connection with the front and rear wheel bearing forks (3-8-4), the front and rear wheel bearing forks (3-8-4) are in bearing connection with the front and rear wheel bearing columns (3-8-5), the front and rear wheel bearing columns (3-8-5) are connected with the front and rear wheels (3-8-6) through bearings, and the connecting straight shaft (3-8-2) is connected with the supporting transmission shaft (3-4).

5. The protective fence equipment for engineering as claimed in claim 1, wherein: the rear wheel mechanism (4) comprises a rotary power motor (4-1), a rotary transmission belt a (4-2), a rotary transmission shaft a (4-3), a rotary gear a (4-4), a rotary connecting plate a (4-5), a rotary gear b (4-6), a rotary transmission shaft b (4-7), a rotary bearing block a (4-8), a rotary bearing block b (4-9), a rotary connecting plate b (4-10), a rotary connecting plate c (4-11), a rotary connecting plate d (4-12), a rotary connecting plate e (4-13), a rotary connecting reset shaft (4-14), a rotary connecting plate f (4-15), a rotary reset spring (4-16), a connecting soft plate a (4-17), a rotary connecting plate g (4-18), A strong magnetic plate (4-19) and a rotary transmission belt b (4-20), wherein the motor shaft of the rotary power motor (4-1) is in friction connection with the rotary transmission belt a (4-2), the rotary transmission belt a (4-2) is in friction connection with the rotary transmission shaft a (4-3), the rotary transmission shaft a (4-3) is connected with the rotary gear a (4-4), the rotary gear a (4-4) is meshed with the rotary gear b (4-6), the rotary connecting plate a (4-5) is in bearing connection with the rotary transmission shaft a (4-3), the rotary gear b (4-6) is connected with the rotary transmission shaft b (4-7), the rotary transmission shaft b (4-7) is connected with a rotary bearing block a (4-8), the rotary bearing block a (4-8) is connected with a rotary bearing block b (4-9), the rotating bearing block b (4-9) is connected with a rotating connecting plate b (4-10), the rotating connecting plate c (4-11) is connected with a rotating connecting plate d (4-12), the rotating connecting plate d (4-12) is connected with a rotating connecting plate f (4-15), the rotating connecting plate e (4-13) is connected with a rotating power motor (4-1), a rotating connecting reset shaft (4-14) is connected with the rotating connecting plate f (4-15) in a sliding way, the rotating connecting plate f (4-15) is connected with a connecting soft plate a (4-17) in a sliding way, a rotating reset spring (4-16) is sleeved on the rotating connecting reset shaft (4-14) and limited on the rotating connecting plate f (4-15) and the rotating connecting plate g (4-18), the connecting soft plate a (4-17) is connected with the rotating connecting plate d (4-12) in a sliding way, the rotary connecting plate g (4-18) is connected with the connecting soft plate a (4-17), the strong magnetic plate (4-19) is connected with the rotary connecting plate g (4-18), the rotary transmission belt b (4-20) is in friction connection with a motor shaft on the rotary power motor (4-1), the rotary transmission shaft b (4-7) is in friction connection with the rotary transmission belt b (4-20), the rotary bearing block a (4-8) is connected with the rotary connecting plate d (4-12), the rotary connecting plate c (4-11) is connected with the mounting plate side plate (1-6), the rotary connecting plate e (4-13) is connected with the mounting plate side plate (1-6), and the connecting soft plate a (4-17) is connected with the mounting plate side plate (1-6).

6. The protective fence equipment for engineering as claimed in claim 1, wherein: the rotating connecting plates d (4-12), the rotating connecting plates f (4-15) and the connecting soft plates a (4-17) are made of high-elasticity rubber and can generate elastic deformation.

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