CN113062333A - Construction method for building rubbish rock block to make slope protection - Google Patents

Abstract

The invention relates to the technical field of construction waste, in particular to a construction method for slope protection by using construction waste rock blocks, which comprises the following steps: step one, crushing and storing building rubbish stones; step two, storing the blended cement; thirdly, spreading the construction waste rock blocks and broken stones in the first step to the revetment; step four, paving the cement neutralized in the step two on the slope protection; the construction method for making the slope protection by using the building rubbish rock blocks also relates to a construction device for making the slope protection by using the building rubbish rock blocks; a construction equipment that bank protection was made to building rubbish rock block includes removal supporting device, bearing rotating device, switching support frame member, slip power device, material aggregate unit, material plugging device, transmission cavity device, lift transmission device and lift adjusting device, removal supporting device on be connected with bearing rotating device, bearing rotating device on rotate and be connected with two switching support frame members.

Description

Construction method for building rubbish rock block to make slope protection

Technical Field

The invention relates to the technical field of construction waste, in particular to a construction method for slope protection by using construction waste rock blocks.

Background

The construction waste refers to residue soil, waste stone, waste material, residual mud and other wastes generated in the process of construction, construction units or individuals constructing, laying, dismantling and repairing various buildings, structures, pipe networks and the like. The waste stone blocks have recycling value, and can be processed into main materials of the revetment, while the prior art can not treat the waste stone blocks, so that the design of the construction device which can make the building rubbish stone blocks into the revetment is particularly important,

disclosure of Invention

The invention relates to the technical field of corrugated pipes, in particular to a construction method for constructing a revetment by building rubbish rock blocks.

The technical scheme adopted by the invention to solve the technical problem is as follows:

a construction method for building rubbish rock blocks to make revetments comprises the following steps:

step one, crushing and storing building rubbish stones;

step two, storing the blended cement;

thirdly, spreading the construction waste rock blocks and broken stones in the first step to the revetment;

step four, paving the cement neutralized in the step two on the slope protection;

the construction method for making the slope protection by using the building rubbish rock blocks also relates to a construction device for making the slope protection by using the building rubbish rock blocks; the construction device for slope protection by building rubbish rock comprises a movable supporting device, a supporting rotating device, switching supporting frame members, a sliding power device, a material linkage device, a material plugging device, a transfer cavity device, a lifting transfer device and a lifting adjusting device, wherein the movable supporting device is connected with the supporting rotating device, the supporting rotating device is rotatably connected with two switching supporting frame members, the two switching supporting frame members are both connected with the sliding power device, the two switching supporting frame members are both slidably connected with the material linkage device, the two material linkage devices are respectively in transmission connection with the two sliding power devices, the two material linkage devices are both connected with the material plugging device, the supporting rotating device is fixedly connected with the two transfer cavity devices, and the two transfer cavity devices are both fixedly connected with the lifting transfer device, the bearing rotating device is fixedly connected with a lifting adjusting device, and the lifting adjusting device is connected with the two switching support frame components in a sliding mode.

The movable supporting device comprises a supporting plate, a supporting cavity, a bearing seat, a switching seat, a worm and a motor I, wherein the four corners of the lower end of the supporting plate are fixedly connected with universal wheels with self-locking functions, the supporting cavity is fixedly connected with the upper part of the supporting plate, a plurality of balls are rotatably connected with the upper part of the supporting cavity, the bearing seat is fixedly connected with the supporting plate, the switching seat is fixedly connected with the bearing seat, the switching seat is rotatably connected with the worm, the motor I is fixedly connected with the switching seat, and the output shaft of the motor I is fixedly connected with the worm.

Bearing rotating device including rotating plectane, center pin, worm wheel and perpendicular board, the below fixedly connected with center pin of rotating the plectane, the center pin rotates with the bearing frame to be connected, fixedly connected with worm wheel on the center pin, the worm wheel is connected with worm drive, rotate plectane and a plurality of ball contact of supporting the cavity top, rotate two perpendicular boards of top fixedly connected with of plectane.

The switching support frame component comprises a support plate, two rotating shafts, two linkage shafts and two notched slideways, the two ends of the support plate are fixedly connected with the rotating shafts, the linkage shafts are fixedly connected to the support plate, the notched slideways are arranged on the support plate, and the two sets of rotating shafts are respectively and rotatably connected with the two vertical plates.

The sliding power device comprises two end fixing plates, two lifting screws and two motors II, wherein the lifting screws are rotatably connected to the end fixing plates, the motors II are fixedly connected to the end fixing plates, output shafts of the motors II are fixedly connected with the lifting screws, the two end fixing plates are respectively and fixedly connected to the outer ends of the two supporting plates, and the inner ends of the two lifting screws are respectively rotatably connected with the two supporting plates.

The material aggregate unit including even bin, toper chamber and smooth chamber of getting, even the below fixedly connected with toper chamber of bin, fixedly connected with slides on the toper chamber and gets chamber and intercommunication, the material aggregate unit be provided with two, two even bin respectively sliding connection pass through threaded transmission with two lift screws in two breach slides and be connected.

The material plugging device comprises switch sliding plates, linkage blocks and telescopic rods, wherein the switch sliding plates are fixedly connected with the linkage blocks, the linkage blocks are fixedly connected with the telescopic rods, the material plugging device is provided with two switch sliding plates which are respectively connected in two sliding cavities, and the two telescopic rods are respectively fixedly connected with the two conical cavities.

The transmission cavity device comprises an upright cavity, an adding cavity and a discharge pipe, wherein the adding cavity is fixedly connected below the upright cavity and communicated with the upright cavity, the discharge pipe is fixedly connected above the upright cavity and communicated with the upright cavity, and the two upright cavities are fixedly connected to a rotating circular plate.

The lifting transmission device comprises a supporting circular plate, a motor III, a transmission shaft and two spiral plates, wherein the supporting circular plate is fixedly connected with the motor III, the transmission shaft is fixedly connected below an output shaft of the motor III, the spiral plates are fixedly connected to the transmission shaft, the two lifting transmission devices are respectively and fixedly connected above two vertical cavities, and the two spiral plates are respectively and slidably connected with the two vertical cavities.

The lifting adjusting device comprises a motor IV, an adjusting screw rod, a cross sliding cavity and right-angle plates, the motor IV is fixedly connected to a rotating circular plate, the adjusting screw rod is fixedly connected to an output shaft of the motor IV, the cross sliding cavity is connected to the adjusting screw rod through threads, the right-angle plates are connected to two ends of the cross sliding cavity in a sliding mode, and the two right-angle plates are respectively connected with the two linkage shafts in a rotating mode.

The construction method for constructing the revetment by using the building rubbish rock blocks has the beneficial effects that:

the invention is convenient to move, can recycle the waste stone blocks, lays the processed waste stone blocks on the slope protection, and then waters cement on the waste stone blocks, thereby realizing the fixation of the waste stone blocks, completing the laying of the slope protection and achieving the waste recycling of the building rubbish stone blocks.

Drawings

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

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a mobile holding apparatus;

FIG. 3 is a schematic view of a supporting and rotating device;

FIG. 4 is a schematic view of the transfer support member and the sliding power unit;

FIG. 5 is a schematic structural view of a material linkage device and a material plugging device;

FIG. 6 is a schematic diagram of a transfer cavity apparatus;

FIG. 7 is a schematic view of the lifting and transferring device;

fig. 8 is a schematic structural view of the lifting adjustment device.

In the figure: moving the supporting device 1; a bearing plate 1-1; a support cavity 1-2; 1-3 of a bearing seat; 1-4 of an adapter; 1-5 parts of worm; motor I1-6; a supporting and rotating device 2; rotating the circular plate 2-1; a central shaft 2-2; 2-3 of worm wheel; 2-4 of a vertical plate; a transfer support frame member 3; a support plate 3-1; a rotating shaft 3-2; 3-3 of a linkage shaft; 3-4 of a notch slideway; a sliding power device 4; end fixing plates 4-1; 4-2 of a lifting screw rod; motor II 4-3; a material linkage device 5; 5-1 of a continuous storage box; a conical cavity 5-2; 5-3 of a sliding cavity; a material plugging device 6; a switch slide 6-1; a linkage block 6-2; 6-3 of a telescopic rod; a transfer cavity means 7; erecting a cavity 7-1; an addition chamber 7-2; a discharge pipe 7-3; a lifting transfer device 8; a supporting circular plate 8-1; motor III 8-2; 8-3 of a transmission shaft; 8-4 parts of spiral plate; a lifting adjusting device 9; motor IV 9-1; adjusting a screw rod 9-2; a sideslip cavity 9-3; and 9-4 of a right-angle plate.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

The technical scheme adopted by the invention to solve the technical problem is as follows:

the first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 8, and a construction method for constructing a revetment by using building waste rock blocks includes the following steps:

step one, crushing and storing building rubbish stones;

step two, storing the blended cement;

thirdly, spreading the construction waste rock blocks and broken stones in the first step to the revetment;

step four, paving the cement neutralized in the step two on the slope protection;

the construction method for making the slope protection by using the building rubbish rock blocks also relates to a construction device for making the slope protection by using the building rubbish rock blocks; the construction device for slope protection by building rubbish rock comprises a movable supporting device 1, a supporting rotating device 2, switching support frame members 3, a sliding power device 4, material linkage devices 5, a material plugging device 6, a transmission cavity device 7, a lifting transmission device 8 and a lifting adjusting device 9, wherein the movable supporting device 1 is connected with the supporting rotating device 2, the supporting rotating device 2 is rotatably connected with two switching support frame members 3, the two switching support frame members 3 are both connected with the sliding power device 4, the two switching support frame members 3 are both slidably connected with the material linkage devices 5, the two material linkage devices 5 are respectively in transmission connection with the two sliding power devices 4, the two material linkage devices 5 are both connected with the material plugging device 6, and the supporting rotating device 2 is fixedly connected with the two transmission cavity devices 7, two transmission cavity devices 7 on all fixedly connected with lift transmission device 8, bearing rotating device 2 on fixedly connected with lift adjusting device 9, lift adjusting device 9 and two switching support frame component 3 sliding connection.

The second embodiment is as follows:

in the following, referring to fig. 1-8, the mobile supporting device 1 includes a supporting plate 1-1, a supporting cavity 1-2, and a bearing seat 1-3, the device comprises adapter bases 1-4, worms 1-5 and motors I1-6, wherein four corners of the lower end of a bearing plate 1-1 are fixedly connected with universal wheels with self-locking, a supporting cavity 1-2 is fixedly connected above the bearing plate 1-1, a plurality of balls are rotatably connected above the supporting cavity 1-2, bearing bases 1-3 are fixedly connected on the bearing plate 1-1, the adapter bases 1-4 are fixedly connected on the bearing plate 1-1, the worms 1-5 are rotatably connected on the adapter bases 1-4, the motors I1-6 are fixedly connected on the adapter bases 1-4, and output shafts of the motors I1-6 are fixedly connected with the worms 1-5;

the supporting plate 1-1 plays a role in bearing and connecting, and the four corners of the lower end of the supporting plate 1-1 are fixedly connected with universal wheels with self-locking, thereby facilitating the movement of the device, the supporting cavity 1-2 can support the rotating round plate 2-1 to protect the rotating round plate 2-1, and a plurality of balls are rotatably connected above the supporting cavity 1-2, so that the friction force between the supporting cavity 1-2 and the rotating circular plate 2-1 can be further reduced, the service life of the rotating circular plate 2-1 is prolonged, the bearing seat 1-3 can provide a rotating space for the central shaft 2-2, the adapter seat 1-4 can provide a rotating space for the worm 1-5, the starting motor I1-6 can drive the worm 1-5 to rotate, and the worm 1-5 can drive the worm wheel 2-3 to rotate.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-8, the bearing rotating device 2 includes a rotating circular plate 2-1, a central shaft 2-2, a worm gear 2-3 and a vertical plate 2-4, the central shaft 2-2 is fixedly connected below the rotating circular plate 2-1, the central shaft 2-2 is rotatably connected with a bearing seat 1-3, the worm gear 2-3 is fixedly connected on the central shaft 2-2, the worm gear 2-3 is in transmission connection with a worm 1-5, the rotating circular plate 2-1 is in contact with a plurality of balls above the supporting cavity 1-2, and two vertical plates 2-4 are fixedly connected above the rotating circular plate 2-1;

the rotating circular plate 2-1 plays a role in bearing connection and can drive the two vertical plates 2-4 to rotate, the central shaft 2-2 can provide a rotating axis for the rotating circular plate 2-1, the worm wheel 2-3 can drive the central shaft 2-2 to rotate to drive the rotating circular plate 2-1 to rotate, the rotating circular plate 2-1 is positioned at different angles to realize that dumping to the abandoned stone blocks and cement is finished, the abandoned stone blocks are firstly paved on a slope protection, the starting motor I1-6 can drive the worm 1-5 to rotate, the worm 1-5 can drive the worm wheel 2-3 to rotate, the rotating worm wheel 2-3 can drive the rotating circular plate 2-1 to rotate, the rotating circular plate 2-1 rotates for half a circle, then the cement is poured on the abandoned stone block, and the fixation of the abandoned stone block is completed.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-8, the switching support frame member 3 includes a support plate 3-1, a rotating shaft 3-2, a linkage shaft 3-3 and a notched slideway 3-4, both ends of the support plate 3-1 are fixedly connected with the rotating shaft 3-2, the linkage shaft 3-3 is fixedly connected to the support plate 3-1, the notched slideway 3-4 is arranged on the support plate 3-1, the switching support frame member 3 is provided with two sets of rotating shafts 3-2, and the two sets of rotating shafts 3-2 are respectively rotatably connected with two vertical plates 2-4;

the support plate 3-1 plays a role in connection, the two rotating shafts 3-2 can provide a rotating space for the support plate 3-1, the support plate 3-1 is enabled to rotate around the two rotating shafts 3-2, the angle of the support plate 3-1 is adjusted by utilizing the lifting of the universal driving shaft 3-3, the angle of the support plate 3-1 is adjusted according to the angle of the slope protection, the angle of the support plate 3-1 is enabled to be the same as that of the slope protection, it is ensured that the abandoned stone can be uniformly laid on the slope protection, and the notched slide way 3-4 can provide a sliding space for the storage box 5-1.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 8, the sliding power device 4 includes two end fixing plates 4-1, two lifting screws 4-2 and two motors II4-3, the lifting screw 4-2 is rotatably connected to the end fixing plate 4-1, the motor II4-3 is fixedly connected to the end fixing plate 4-1, an output shaft of the motor II4-3 is fixedly connected to the lifting screw 4-2, the sliding power device 4 is provided with two end fixing plates 4-1, the two end fixing plates 4-1 are respectively and fixedly connected to the outer ends of the two supporting plates 3-1, and the inner ends of the two lifting screws 4-2 are respectively and rotatably connected to the two supporting plates 3-1;

the end fixing plate 4-1 plays a role of fixing and supporting, the starting motor II4-3 can drive the lifting screw rod 4-2 to rotate, the rotating lifting screw rod 4-2 can drive the storage box 5-1 to slide, and when the abandoned stone blocks are laid or cement is poured, the storage box 5-1 is slowly driven to slide, so that the abandoned stone blocks and the cement are uniformly laid on the slope protection.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-8, the material linkage device 5 includes a storage box 5-1, a conical cavity 5-2 and a sliding cavity 5-3, the conical cavity 5-2 is fixedly connected below the storage box 5-1, the sliding cavity 5-3 is fixedly connected to the conical cavity 5-2 and communicated with the storage box, two material linkage devices 5 are provided, and the two storage boxes 5-1 are respectively connected in the two notched slideways 3-4 in a sliding manner and are respectively connected with the two lifting screws 4-2 through thread transmission;

abandoned stones and cement are respectively stored in the two storage boxes 5-1 and can be discharged through the two conical cavities 5-2, and the conical cavities 5-2 can reduce the area of a material falling opening, so that the materials are convenient to slide on a slope protection with uniform materials, and the sliding cavities 5-3 can provide sliding space for the switch sliding plates 6-1.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 8, the material plugging device 6 includes two switch sliding plates 6-1, two linkage blocks 6-2 and two telescopic rods 6-3, the linkage block 6-2 is fixedly connected to the switch sliding plate 6-1, the telescopic rod 6-3 is fixedly connected to the linkage block 6-2, the two switch sliding plates 6-1 are respectively slidably connected to the two sliding cavities 5-3, and the two telescopic rods 6-3 are respectively fixedly connected to the two conical cavities 5-2;

when the abandoned stone blocks or cement are required to be discharged, the corresponding telescopic rods 6-3 can be started, the switch sliding plate 6-1 is driven to slide through the linkage block 6-2, and the abandoned stone blocks or cement are discharged from the conical cavity 5-2 and fall onto the slope protection.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1-8, the transfer cavity device 7 includes a vertical cavity 7-1, an adding cavity 7-2 and a discharging pipe 7-3, the adding cavity 7-2 is fixedly connected and communicated with the lower part of the vertical cavity 7-1, the discharging pipe 7-3 is fixedly connected and communicated with the upper part of the vertical cavity 7-1, two transfer cavity devices 7 are provided, and the two vertical cavities 7-1 are fixedly connected to a rotating circular plate 2-1;

the vertical cavity 7-1 plays a role in bearing connection, waste stone blocks or cement are added to the vertical cavity 7-1 through the adding cavity 7-2, the waste stone blocks or cement can be discharged from the discharging pipe 7-3 at last, the two discharging pipes 7-3 are respectively positioned above the two storage boxes 5-1, and finally the waste stone blocks or cement can respectively fall into the two storage boxes 5-1 to finish classification of the waste stone blocks and the cement.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 8, the lifting transmission device 8 includes a supporting circular plate 8-1, a motor III8-2, a transmission shaft 8-3 and a spiral plate 8-4, the supporting circular plate 8-1 is fixedly connected with the motor III8-2, the transmission shaft 8-3 is fixedly connected below an output shaft of the motor III8-2, the spiral plate 8-4 is fixedly connected to the transmission shaft 8-3, the lifting transmission device 8 is provided with two supporting circular plates 8-1, the two supporting circular plates 8-1 are respectively fixedly connected above the two standing cavities 7-1, and the two spiral plates 8-4 are respectively connected with the two standing cavities 7-1 in a sliding manner;

after the abandoned stone blocks or cement are added into the two adding cavities 7-2, the motor III8-2 is started to drive the transmission shaft 8-3 to rotate, the transmission shaft 8-3 can drive the spiral plates 8-4 to rotate, the rotation of the two spiral plates 8-4 is utilized to drive the abandoned stone blocks or cement to move upwards, and finally the abandoned stone blocks or cement are discharged by the two discharge pipes 7-3 and fall into the two storage tanks 5-1.

The detailed implementation mode is ten:

the embodiment is described below with reference to fig. 1-8, wherein the lifting adjusting device 9 includes a motor IV9-1, an adjusting screw 9-2, a transverse sliding cavity 9-3 and a right-angle plate 9-4, the motor IV9-1 is fixedly connected to a rotating circular plate 2-1, an output shaft of the motor IV9-1 is fixedly connected to the adjusting screw 9-2, the adjusting screw 9-2 is connected to the transverse sliding cavity 9-3 through a thread, both ends of the transverse sliding cavity 9-3 are slidably connected to the right-angle plate 9-4, and the two right-angle plates 9-4 are respectively rotatably connected to two universal driving shafts 3-3;

according to the angle of the slope protection, the starting motor IV9-1 drives the adjusting screw rod 9-2 to rotate, the rotating adjusting screw 9-2 can drive the horizontal sliding cavity 9-3 to lift, the horizontal sliding cavity 9-3 can drive the two right-angle plates 9-4 to lift, two right-angle plates 9-4 are respectively connected with two linkage shafts 3-3 in a rotating way to drive two support plates 3-1 to rotate around two groups of rotating shafts 3-2, when the two supporting plates 3-1 rotate, the position of the linkage shaft 3-3 is also changed, at this moment, the two right-angle plates 9-4 can slide in the transverse sliding cavity 9-3, the rotation of the two supporting plates 3-1 cannot be influenced, the angles of the two supporting plates 3-1 and the slope protection are the same, and therefore the condition that the abandoned stone blocks and the cement fall on the slope protection evenly can be ensured.

The invention relates to a construction method for constructing a revetment by building rubbish rock blocks, which has the use principle that:

the supporting plate 1-1 plays a role in bearing connection, universal wheels with self-locking are fixedly connected at four corners of the lower end of the supporting plate 1-1, the device is convenient to move, the supporting cavity 1-2 can support the rotating circular plate 2-1 to protect the rotating circular plate 2-1, a plurality of balls are rotatably connected above the supporting cavity 1-2, the friction force between the supporting cavity 1-2 and the rotating circular plate 2-1 can be further reduced, the service life of the rotating circular plate 2-1 is prolonged, the bearing seat 1-3 can provide a rotating space for the central shaft 2-2, the adapter seat 1-4 can provide a rotating space for the worm 1-5, the starting motor I1-6 can drive the worm 1-5 to rotate, and the worm 1-5 can drive the worm wheel 2-3 to rotate, according to the angle of the slope protection, a starting motor IV9-1 drives an adjusting screw 9-2 to rotate, the rotating adjusting screw 9-2 can drive a transverse sliding cavity 9-3 to lift, the transverse sliding cavity 9-3 can drive two right-angle plates 9-4 to lift, the two right-angle plates 9-4 are respectively in rotating connection with two linkage shafts 3-3 to drive two support plates 3-1 to rotate around two groups of rotating shafts 3-2, when the two support plates 3-1 rotate, the positions of the linkage shafts 3-3 can be changed, at the moment, the two right-angle plates 9-4 can slide in the transverse sliding cavity 9-3, the rotation of the two support plates 3-1 cannot be influenced, the two support plates 3-1 have the same angle with the slope protection, and therefore, the waste stone blocks and cement can be ensured to uniformly fall on the slope protection, the bearing plate 1-1 plays a role of bearing connection, four corners at the lower end of the bearing plate 1-1 are fixedly connected with universal wheels with self-locking, the movement of the device is convenient, the supporting plate 3-1 plays a role of connection, two rotating shafts 3-2 can provide rotating space for the supporting plate 3-1, the supporting plate 3-1 can rotate around the two rotating shafts 3-2, the angle of the supporting plate 3-1 is adjusted by utilizing the lifting of the linkage shaft 3-3, the angle of the supporting plate 3-1 is adjusted according to the angle of the slope protection, the angle of the supporting plate 3-1 is the same as that of the slope protection, the waste stone blocks can be uniformly laid on the slope protection, the notched slide ways 3-4 can provide sliding space for the storage box 5-1, the end fixing plate 4-1 plays a role of fixed support, the starting motor II4-3 can drive the lifting screw rod 4-2 to rotate, the rotating lifting screw 4-2 can drive the storage box 5-1 to slide, when the abandoned stone blocks are laid or cement is poured, the storage box 5-1 is slowly driven to slide, the abandoned stone blocks and the cement are uniformly laid on the slope protection, the abandoned stone blocks and the cement are respectively stored in the two storage boxes 5-1 and can be discharged through the two conical cavities 5-2, the area of a material falling opening can be reduced due to the conical cavities 5-2, the material is conveniently and uniformly laid on the slope protection, the sliding cavity 5-3 can provide a sliding space for the switch sliding plate 6-1, the vertical cavity 7-1 plays a role in bearing connection, the abandoned stone blocks or the cement are added onto the vertical cavity 7-1 through the adding cavity 7-2, finally the abandoned stone blocks or the cement can be discharged from the discharge pipe 7-3, the two discharge pipes 7-3 are respectively positioned above the two storage boxes 5-1, finally, the abandoned stone blocks or cement can respectively fall into the two storage boxes 5-1 to finish classification of the abandoned stone blocks and the cement, after the abandoned stone blocks or the cement are added into the two adding cavities 7-2, the motor III8-2 is started to drive the transmission shaft 8-3 to rotate, the transmission shaft 8-3 can drive the spiral plates 8-4 to rotate, the rotation of the two spiral plates 8-4 is utilized to drive the abandoned stone blocks or the cement to move upwards, finally, the abandoned stone blocks or the cement can be discharged from the two discharge pipes 7-3 and fall into the two storage boxes 5-1, when the abandoned stone blocks or the cement need to be discharged, the corresponding telescopic rods 6-3 can be started, the linkage blocks 6-2 drive the switch slide plates 6-1 to slide, the abandoned stone blocks or the cement are discharged from the conical cavities 5-2 and fall onto a slope protection, the support cavities 1-2 can support the rotary circular plates 2-1, the rotary round plate 2-1 is protected, a plurality of balls are rotatably connected above the supporting cavity 1-2, friction force between the supporting cavity 1-2 and the rotary round plate 2-1 can be further reduced, the service life of the rotary round plate 2-1 is prolonged, the bearing seat 1-3 can provide a rotating space for the central shaft 2-2, the adapter seat 1-4 can provide a rotating space for the worm 1-5, the starting motor I1-6 can drive the worm 1-5 to rotate, the worm 1-5 can drive the worm wheel 2-3 to rotate, cement is replaced to be discharged, and after the cement falls onto the abandoned stone block, the cement is smeared to finish fixing the abandoned stone block.

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 (10)

1. A construction method for slope protection by building rubbish rock blocks is characterized in that: the method comprises the following steps:

step one, crushing and storing building rubbish stones;

step two, storing the blended cement;

thirdly, spreading the construction waste rock blocks and broken stones in the first step to the revetment;

step four, paving the cement neutralized in the step two on the slope protection;

the construction method for making the slope protection by using the building rubbish rock blocks also relates to a construction device for making the slope protection by using the building rubbish rock blocks; the construction device for slope protection by building rubbish rock comprises a movable supporting device (1), a supporting rotating device (2), transfer supporting frame members (3), a sliding power device (4), a material linkage device (5), a material plugging device (6), a transfer cavity device (7), a lifting transfer device (8) and a lifting adjusting device (9), wherein the movable supporting device (1) is connected with the supporting rotating device (2), the supporting rotating device (2) is rotatably connected with the two transfer supporting frame members (3), the two transfer supporting frame members (3) are both connected with the sliding power device (4), the two transfer supporting frame members (3) are both slidably connected with the material linkage device (5), and the two material linkage devices (5) are respectively in transmission connection with the two sliding power devices (4), two material aggregate unit (5) on all be connected with material plugging device (6), bearing rotating device (2) on two transmission cavity devices of fixedly connected with (7), two transmission cavity device (7) on all fixedly connected with lift transmission device (8), bearing rotating device (2) on fixedly connected with lift adjusting device (9), lift adjusting device (9) and two switching support frame members (3) sliding connection.

2. The process for preparing a corrugated pipe according to claim 1, wherein: the movable supporting device (1) comprises a supporting plate (1-1), a supporting cavity (1-2), a bearing seat (1-3), an adapter seat (1-4), a worm (1-5) and a motor I (1-6), wherein universal wheels with self-locking are fixedly connected at four corners of the lower end of the supporting plate (1-1), the supporting cavity (1-2) is fixedly connected above the supporting plate (1-1), a plurality of balls are rotatably connected above the supporting cavity (1-2), the bearing seat (1-3) is fixedly connected on the supporting plate (1-1), the adapter seat (1-4) is fixedly connected on the supporting plate (1-1), the worm (1-5) is rotatably connected on the adapter seat (1-4), and the motor I (1-6) is fixedly connected on the adapter seat (1-4), the output shaft of the motor I (1-6) is fixedly connected with the worm (1-5).

3. The construction method for slope protection by building rubbish rock blocks as claimed in claim 2, wherein: the bearing rotating device (2) comprises a rotating circular plate (2-1), a central shaft (2-2), a worm wheel (2-3) and vertical plates (2-4), wherein the central shaft (2-2) is fixedly connected to the lower portion of the rotating circular plate (2-1), the central shaft (2-2) is rotatably connected with the bearing seat (1-3), the worm wheel (2-3) is fixedly connected to the central shaft (2-2), the worm wheel (2-3) is in transmission connection with a worm (1-5), the rotating circular plate (2-1) is in contact with a plurality of balls above the supporting cavity (1-2), and the two vertical plates (2-4) are fixedly connected to the upper portion of the rotating circular plate (2-1).

4. The construction method for slope protection by building rubbish rock blocks as claimed in claim 3, wherein: the switching support frame component (3) comprises a support plate (3-1), two rotating shafts (3-2), two linkage shafts (3-3) and two notched slideways (3-4), wherein the two ends of the support plate (3-1) are fixedly connected with the rotating shafts (3-2), the linkage shafts (3-3) are fixedly connected to the support plate (3-1), the notched slideways (3-4) are arranged on the support plate (3-1), the switching support frame component (3) is provided with two groups of rotating shafts (3-2), and the two groups of rotating shafts (3-2) are respectively rotatably connected with the two vertical plates (2-4).

5. The construction method for slope protection by building rubbish rock blocks as claimed in claim 4, wherein the construction method comprises the following steps: the sliding power device (4) comprises end fixing plates (4-1), lifting screw rods (4-2) and motors II (4-3), wherein the end fixing plates (4-1) are rotatably connected with the lifting screw rods (4-2), the end fixing plates (4-1) are fixedly connected with the motors II (4-3), output shafts of the motors II (4-3) are fixedly connected with the lifting screw rods (4-2), the sliding power device (4) is provided with two end fixing plates (4-1), the two end fixing plates are respectively and fixedly connected to the outer ends of the two supporting plates (3-1), and the inner ends of the two lifting screw rods (4-2) are respectively and rotatably connected with the two supporting plates (3-1).

6. The construction method for slope protection by building rubbish rock blocks as claimed in claim 5, wherein: the material linkage device (5) comprises a storage box (5-1), a conical cavity (5-2) and a sliding taking cavity (5-3), wherein the conical cavity (5-2) is fixedly connected with the lower part of the storage box (5-1), the conical cavity (5-2) is fixedly connected with the sliding taking cavity (5-3) and communicated, the two storage boxes (5) are connected with each other, are respectively connected in two notch slideways (3-4) in a sliding manner and are respectively connected with the two lifting screws (4-2) through thread transmission, and the two storage boxes (5-1) are respectively connected with the two lifting screws (4-2).

7. The construction method for slope protection by building rubbish rock blocks as claimed in claim 6, wherein: the material plugging device (6) comprises two switch sliding plates (6-1), linkage blocks (6-2) and telescopic rods (6-3), the linkage blocks (6-2) are fixedly connected to the switch sliding plates (6-1), the telescopic rods (6-3) are fixedly connected to the linkage blocks (6-2), the two switch sliding plates (6-1) are respectively connected to the two sliding cavities (5-3) in a sliding mode, and the two telescopic rods (6-3) are respectively fixedly connected with the two conical cavities (5-2).

8. The construction method for slope protection by building rubbish rock blocks as claimed in claim 7, wherein: the transmission cavity device (7) comprises a vertical cavity (7-1), an adding cavity (7-2) and a discharge pipe (7-3), the adding cavity (7-2) is fixedly connected and communicated with the lower portion of the vertical cavity (7-1), the discharge pipe (7-3) is fixedly connected and communicated with the upper portion of the vertical cavity (7-1), the number of the transmission cavity device (7) is two, and the two vertical cavities (7-1) are fixedly connected to a rotating circular plate (2-1).

9. The construction method of building rubbish rock block slope protection according to claim 8, characterized in that: the lifting transmission device (8) comprises a supporting circular plate (8-1), a motor III (8-2), a transmission shaft (8-3) and spiral plates (8-4), wherein the supporting circular plate (8-1) is fixedly connected with the motor III (8-2), the transmission shaft (8-3) is fixedly connected below an output shaft of the motor III (8-2), the spiral plates (8-4) are fixedly connected on the transmission shaft (8-3), the lifting transmission device (8) is provided with two supporting circular plates (8-1), the two supporting circular plates (8-1) are respectively and fixedly connected above the two vertical cavities (7-1), and the two spiral plates (8-4) are respectively and slidably connected with the two vertical cavities (7-1).

10. The construction method for slope protection by building rubbish rock blocks as claimed in claim 4, wherein the construction method comprises the following steps: the lifting adjusting device (9) comprises a motor IV (9-1), an adjusting lead screw (9-2), a transverse sliding cavity (9-3) and right-angle plates (9-4), the motor IV (9-1) is fixedly connected to the rotating circular plate (2-1), the adjusting lead screw (9-2) is fixedly connected to an output shaft of the motor IV (9-1), the adjusting lead screw (9-2) is connected to the transverse sliding cavity (9-3) through threads, the right-angle plates (9-4) are connected to two ends of the transverse sliding cavity (9-3) in a sliding mode, and the two right-angle plates (9-4) are respectively connected with the two universal driving shafts (3-3) in a rotating mode.

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