CN212639788U

CN212639788U - Building secondary structure material loading machine

Info

Publication number: CN212639788U
Application number: CN202021130937.8U
Authority: CN
Inventors: 曹生然
Original assignee: Shengran Construction Machinery Factory In Jinan New Area
Current assignee: Shengran Construction Machinery Factory In Jinan New Area
Priority date: 2020-06-18
Filing date: 2020-06-18
Publication date: 2021-03-02
Anticipated expiration: 2030-06-18

Abstract

Building secondary structure material loading machine, including lifting machine, helical drum and chassis, its characterized in that: the front part of the receiving hopper of the elevator is welded with the hooking device, the feeding hopper of the elevator is pulled by the winch through the steel wire rope I to ascend along the steel wire rope II, the feeding hopper is hooked by the hooking device when ascending to the position of the receiving hopper, and the feeding hopper continuously ascends to complete the feeding of the material into the receiving hopper. The bottom surface of the receiving hopper is a front-high rear-low inclined plane, the lower part of the rear end of the receiving hopper is provided with a hole communicated with the spiral roller, the side surface of the upper part of the spiral roller is provided with an upper discharge hole, the discharge hole is connected with a discharge pipe through a discharge interface and an outlet clamp, and materials are conveyed to the discharge pipe through a spiral manner to complete material conveying. Compared with the prior art, the utility model discloses not only can promote thick liquids, also can promote the lump material, still greatly reduced operating personnel's intensity of labour, improve production efficiency.

Description

Building secondary structure material loading machine

Technical Field

The utility model relates to a building field especially relates to building secondary structure construction, specifically indicates building secondary structure material loading machine.

Background

At present, the labor intensity of workers for loading materials in the construction of the secondary structure of the building is high, and the efficiency is low; only the slurry can be lifted at the same time, and the function is single; therefore, the design of a novel building secondary structure feeding machine is a technical problem which needs to be solved at present.

Disclosure of Invention

The utility model aims to solve the technical problem that a building secondary structure material loading machine is provided.

The technical proposal of the utility model for solving the technical problem is that: building secondary structure material loading machine, including lifting machine, helical drum and chassis, its characterized in that: the welding has the crochet hook ware on the anterior of the hopper that connects of lifting machine, and the hopper of lifting machine is drawn through I wire rope by the hoist engine and is risen along wire rope II, is hooked by the crochet hook ware when the hopper rises to connect the hopper position, and the hopper continues to rise and accomplishes promptly and send into the material and connect the hopper.

As the utility model discloses an optimal scheme, the bottom surface that connects the hopper be preceding high back low type inclined plane, connect the porose spiral cylinder that is communicateing in the rear end lower part of hopper, the upper portion side of spiral cylinder is provided with the top discharge mouth, the discharging pipe is being connected through ejection of compact interface, export clamp to the discharge gate, the material is carried the discharging pipe through the spiral and is accomplished the material and carry.

The chassis is rectangular, the two sides of the middle part below the chassis are respectively welded with a directional pipe, the middle parts of the two sides above the chassis, namely the upper parts of the directional pipes, are respectively welded with a vertical channel steel, a slotted pipe is welded on the vertical channel steel, supporting pipes are respectively and slidably installed in the two directional pipes and the slotted pipe, a winch is connected below the chassis, rope guide pipes are respectively welded on the two sides of the upper part of the front part of the chassis, upper long pipes are respectively welded on the upper ends of the two supporting pipes, the direction of the upper long pipes is vertical to the connecting line between the two supporting pipes, a lacing wire II is welded between the two upper long pipes in the middle part of the upper long pipes, pulley shaft brackets I are respectively welded behind the middle lacing wires II of the two upper long pipes, pulley shafts I are installed on the two pulley shaft brackets I, pulleys I are installed in the middle parts of the pulley shafts I, adjustable pipes are respectively sleeved on the front sections of the two upper, pulley shafts II are mounted on the two pulley shaft brackets II, pulleys II are mounted in the middle of the pulley shafts II, pulley carriages are welded below the rear portions of the adjustable pipes respectively, pulleys are mounted on the pulley carriages, a jacking wire seat is welded behind the pulley carriages below the rear portions of the adjustable pipes, jacking wires are mounted on the jacking wire seat, the rear sections of the two upper long pipes are sleeved with the fixed pipes respectively, jacking wire seats are welded below the front portions of the fixed pipes respectively, jacking wires are mounted on the jacking wire seats, and tie bars I are connected between the two fixed pipes.

As the utility model discloses a another kind of preferred scheme, the intraductal cartridge of rope guide has rope guide I, is connecting rope guide II perpendicularly at the front end of rope guide I, and rope guide I is porose with II junctions of rope guide, and the downthehole stub shaft that is connecting, the rope guide cover is being put at the jacket on the stub shaft, and the hypomere front side of rope guide II is connected with rope guide wheel seat, installs the rope guide wheel on the rope guide wheel seat, and the top wire seat is being welded to the higher authority of rope guide, installs the jackscrew on the top wire seat.

As another preferred scheme of the utility model, two fluting pipe upper segments welded the connecting plate respectively, the supporting seat is being installed on the connecting plate, install the lifting roller between two supporting seats, twine wire rope III on the lifting roller, the hypomere of two spinal branch stay tubes respectively with the preceding welding of connecting plate I, the welded position of two connecting plates I will with the elongated slot position phase-match of fluting pipe, two I connecting plates are connected respectively at the both ends of lifting bar at the back, the welding has rings above the centre of lifting bar, rings are connecting wire rope III's the other end, use the spanner to pull the lifting roller and make two spinal branch stay tubes lifting upwards.

As the utility model discloses a preferred scheme still has the support to connect the pole below two spinal branch stay tubes, the support connect the pole including connecting the pole, connect the upper end fixed connection connector of pole, connect the hypomere of pole and be connected with connecting plate I respectively, two connecting plates I are connected respectively at the both ends of lifter, the welding has rings II above the centre of lifter, rings II are connecting wire rope III's the other end.

As another preferred scheme of the utility model, the utility model also comprises a feeding hopper, the feeding hopper comprises a hopper, the side of the hopper is a semi-circular front part and a rectangular rear part, a fixed shaft is respectively welded on the outer sides of the middle parts of the two side surfaces, a movable sleeve is arranged on the fixed shaft, a movable arm is welded on the movable sleeve, the top ends of the two movable arms are welded on the two ends of a lifting rod I, a lifting ring I is welded on the middle part of the lifting rod I, a sleeve is respectively welded on the outer side of the rear part of the hopper, a rotating shaft passes through the sleeve, a shaft is arranged at the inner side end of the rotating shaft and is connected with the rotating shaft through a baffle plate, a clamping plate I is welded on the outer side end of the rotating shaft, two guide wheel shafts are welded on the clamping plate I, a guide wheel is arranged on the guide wheel shaft, a clamping plate II is arranged outside the guide wheel and, a supporting rod is connected between the two supporting tubes, and a hinge is connected with the supporting rod.

As the utility model discloses a still another preferred scheme, change the feeding funnel into feeding tray, feeding tray include the tray, connecting on the tray and lifting by crane the lacing wire, lifting rod II is being connected on the top of lifting by crane the lacing wire, the welding has rings above lifting rod II's centre, there is the landing leg below the front end of tray, the sleeve pipe has been welded respectively in the rear portion both sides face outside of tray, the pivot has been worn in the sleeve pipe, the side has the axle to be connected with the pivot with the separation blade in the pivot, the end welding has splint I outside the pivot, the welding has two leading wheel axles on splint I, the leading wheel is installed to the leading wheel epaxial, splint II and screw locking are being installed to the outside of leading wheel.

As another preferred scheme of the utility model, the spiral roller comprises a lower roller cover, the outer ring on the lower roller cover is connected with a roller shell, the lower part of the roller shell is a conical shape with the upper part of the cylinder being big at the bottom and small at the top, an upper roller cover is connected with the top of the upper part of the roller shell, an upper positioning sleeve is connected with the middle of the lower part of the upper roller cover, an upper discharge port is connected with the side surface of the upper part of the roller shell, the upper discharge port is connected with a discharge pipe through a discharge port and an outlet clamp, a lower discharge port is connected with the side surface of the lower part of the roller shell, the lower discharge port is blocked by the discharge port, a connecting shaft head is arranged in the middle of the lower roller cover, the upper end of the connecting shaft head is connected with a spiral shaft, the spiral shaft comprises spiral blades with different, the welding position of the support plate is matched with the position of the long groove of the grooved tube, a spiral rolling motor is installed on the motor support, a motor chain wheel is installed on the spiral rolling motor, the position of the motor chain wheel is matched with the position of the roller chain wheel, the motor chain wheel is connected with the roller chain wheel through a chain, and a tensioning ring is welded in the middle of the outer side of the spiral roller.

As the utility model discloses a still another preferred scheme, the screw axis with in the spiral cylinder is changed to half screw axis, and the discharge gate is stopped up with the discharge gate plug, and the lower discharge gate passes through ejection of compact interface and export clamp connection the discharging pipe can.

Compared with the prior art, the utility model discloses not only can promote thick liquids, also can promote the lump material, still greatly reduced operating personnel's intensity of labour, improve production efficiency.

Drawings

FIG. 1 is a schematic structural view of a feeding machine for a secondary structure of a building;

FIG. 2 is a top view of a building secondary structure feeder;

FIG. 3 is a schematic diagram of the operation of the hopper;

FIG. 4 is a schematic view of the feeding tray after replacing the hopper;

FIG. 5 is a top view of FIG. 4;

FIG. 6 is a cross-sectional view E-E of FIG. 1;

FIG. 7 is an enlarged view of a portion of FIG. 1 at A;

FIG. 8 is an enlarged view of a portion of FIG. 3 at B;

FIG. 9 is a schematic view after being raised using a support extension bar;

FIG. 10 is an enlarged view of a portion of FIG. 3 at D;

FIG. 11 is a schematic view of the hopper construction;

FIG. 12 is a top view of the hopper;

FIG. 13 is an enlarged view of a portion of FIG. 12 at C;

FIG. 14 is a schematic structural view of a loading tray;

FIG. 15 is a top view of the feeding tray;

FIG. 16 is a schematic view of a support rod structure;

FIG. 17 is a top view of FIG. 16;

FIG. 18 is a left side view of FIG. 16;

FIG. 19 is a schematic view of a spiral drum structure;

FIG. 20 is a schematic view of a screw axis structure;

FIG. 21 is a top view of FIG. 20;

FIG. 22 is a schematic view of a half-spiral shaft configuration;

FIG. 23 is a top view of FIG. 22;

FIG. 24 is a schematic view of a discharge hole plug;

fig. 25 is a view taken along direction K in fig. 1.

Detailed Description

As shown in the figure, the building secondary structure feeding machine comprises a lifting machine, a spiral roller 6 and a movable chassis 10, wherein a hooking device 1-1 is welded on the front part of a receiving hopper 1 of the lifting machine, a feeding hopper 2 of the lifting machine is pulled by a winch 3 through a steel wire rope I4 to ascend along a steel wire rope II 5, when the feeding hopper 2 ascends to the position of the receiving hopper 1, the feeding hopper 2 is hooked by the hooking device 1-1, and the feeding hopper 2 continuously ascends to complete the feeding of materials into the receiving hopper 1.

The bottom surface of the receiving hopper 1 is a slope with a high front part and a low rear part, the lower part of the rear end of the receiving hopper 1 is provided with a hole communicated with a spiral roller 6, the side surface of the upper part of the spiral roller 6 is provided with an upper discharge port 6-7, the discharge port 6-7 is connected with a discharge pipe 19 through a discharge interface 7 and an outlet clamp 8, and materials are conveyed to the discharge pipe 19 through a spiral manner to complete material conveying.

The movable chassis 10 is rectangular, the two sides of the middle part below the movable chassis 10 are respectively welded with a directional pipe 15, the middle parts of the two sides above the movable chassis 10, namely the upper parts of the directional pipes 15, are respectively welded with a vertical channel steel 20, a slotted pipe 22 is welded on the vertical channel steel 20, two supporting pipes 21 are respectively arranged in the two directional pipes 15 and the slotted pipe 22 in a sliding way, the lower part of the movable chassis 10 is connected with a winch 3, the two sides of the upper part of the front part of the movable chassis 10 are respectively welded with a rope guiding pipe 18, the upper ends of the two supporting pipes 21 are respectively welded with an upper long pipe 26, the direction of the upper long pipe 26 is vertical to the connecting line between the two supporting pipes 21, a lacing bar II 30 is welded between the two upper long pipes 26, a pulley shaft bracket I31 is respectively welded behind the middle lacing bars II 30 of the two upper long pipes 26, and a pulley shaft I32, a pulley I33 is mounted in the middle of a pulley shaft I32, adjustable pipes 27 are sleeved on the front sections of two upper long pipes 26 respectively, pulley shaft brackets II 34 are welded on the inner sides of the front ends of the adjustable pipes 27 respectively, pulley shafts II 35 are mounted on the two pulley shaft brackets II 34, pulleys II 36 are mounted in the middle of the pulley shafts II 35, pulley brackets 37 are welded on the lower portions of the rear portions of the adjustable pipes 27 respectively, pulleys 38 are mounted on the pulley brackets 37, a jacking wire seat 39 is welded on the rear portion of the pulley bracket 37 below the rear portion of the adjustable pipes 27, jacking wires 40 are mounted on the jacking wire seat 39, fixed pipes 28 are sleeved on the rear portions of the two upper long pipes 26 respectively, jacking wire seats 39 are welded on the lower portions of the front portions of the fixed pipes 28 respectively, jacking wires 40 are mounted on the jacking wire seats 39, and tie rods I29 are connected between the two fixed pipes 28.

A rope guide pipe I41 is inserted in the rope guide pipe 18, the front end of the rope guide pipe I41 is vertically connected with a rope guide pipe II 42, a hole is formed in the joint of the rope guide pipe I41 and the rope guide pipe II 42, a small shaft 43 is connected in the hole, a rope guide sleeve 44 is sleeved on the small shaft 43, the front side of the lower section of the rope guide pipe II 42 is connected with a rope guide wheel seat 45, a rope guide wheel 46 is installed on the rope guide wheel seat 45, a top thread seat 39 is welded on the upper surface of the rope guide pipe 18, and a top thread 40 is installed on the top thread seat 39.

The upper sections of the two slotted pipes 22 are respectively welded with a connecting plate 25, the connecting plate 25 is provided with a supporting seat 24, a lifting roller 23 is arranged between the two supporting seats 24, a steel wire rope III 47 is wound on the lifting roller 23, the lower sections of the two supporting pipes 21 are respectively welded with the front of a connecting plate I48-3, the welding position of the two connecting plates I48-3 is matched with the position of an elongated slot of the slotted pipe 22, the rear parts of the two connecting plates I48-3 are respectively connected with the two ends of a lifting rod 48-2, the middle part of the lifting rod 48-2 is welded with a lifting ring II 48-5, the lifting ring II 48-5 is connected with the other end of the steel wire rope III 47, and a wrench 51 is used for pulling the lifting roller 23.

The supporting connecting rods 48 are arranged below the two supporting pipes 21 and comprise connecting rods 48-1, the upper ends of the connecting rods 48-1 are fixedly connected with connectors 48-4, the lower sections of the connecting rods 48-1 are respectively connected with connecting plates I48-3, the two connecting plates I48-3 are respectively connected to the two ends of a lifting rod 48-2, a lifting ring II 48-5 is welded on the middle of the lifting rod 48-2, and the lifting ring II 48-5 is connected with the other end of a steel wire rope III 47.

The automatic feeding device also comprises a feeding hopper 2, the feeding hopper 2 comprises a hopper 2-1, the side face of the hopper 2-1 is a semicircular front part, the rear part is a rectangle, fixed shafts 2-5 are respectively welded on the outer sides of the middle parts of the two side faces, movable sleeves 2-4 are arranged on the fixed shafts 2-5, movable arms 2-3 are welded on the movable sleeves 2-4, the top ends of the two movable arms 2-3 are welded at the two ends of a lifting rod I2-2, a lifting ring I2-6 is welded on the middle part of the lifting rod I2-2, sleeves 2-7 are respectively welded on the outer sides of the rear part of the hopper 2-1, a rotating shaft 2-8 is penetrated in each sleeve 2-7, the inner side end of the rotating shaft 2-8 is connected with the rotating shaft 2-8 through a shaft baffle 2-9, and the, two guide wheel shafts 2-12 are welded on the clamping plates I2-10, guide wheels 2-11 are installed on the guide wheel shafts 2-12, clamping plates II 2-13 are installed outside the guide wheels 2-11 and locked by screws, the receiving hopper 1 comprises a receiving dustpan 1-3, a rope passing pipe 1-2 is welded on the middle part of the receiving dustpan 1-3, a hinge 1-4 is welded on the lower part of the middle part of the receiving dustpan 1-3, a supporting rod 50 is connected between the two supporting tubes 21, and the hinge 1-4 is connected with the supporting rod 50.

The hopper 2 is replaced by a feeding tray 49, said feeding tray 49 comprises a tray 49-1,

a lifting lacing wire 49-3 is connected on the tray 49-1, a lifting rod II 49-4 is connected at the top end of the lifting lacing wire 49-3, a lifting ring I2-6 is welded on the middle of the lifting rod II 49-4, a supporting leg 49-2 is arranged below the front end of the tray 49-1, sleeves 2-7 are respectively welded on the outer sides of two side faces of the rear part of the tray 49-1, a rotating shaft 2-8 penetrates through the sleeves 2-7, the inner side end of the rotating shaft 2-8 is provided with a shaft which is connected with the rotating shaft 2-8 through a baffle plate 2-9, the outer side end of the rotating shaft 2-8 is welded with a clamping plate I2-10, two guide wheel shafts 2-12 are welded on the clamping plates I2-10, guide wheels 2-11 are arranged on the guide wheel shafts 2-12, and clamping plates II 2-13 are arranged outside the guide wheels 2-11 and are locked by screws.

The spiral roller 6 comprises a roller lower cover 6-6, the outer ring on the roller lower cover 6-6 is connected with a roller shell 6-1, the lower part of the roller shell 6-1 is in a conical shape with the upper part of the cylinder being big at the bottom and small at the top, the roller upper cover 6-3 is connected with the top of the upper part of the roller shell 6-1, the middle of the lower part of the roller upper cover 6-3 is connected with an upper positioning sleeve 6-4, the side surface of the upper part of the roller shell 6-1 is connected with an upper discharge port 6-7, the upper discharge port 6-7 is connected with a discharge pipe 19 through a discharge interface 7 and an outlet clamp 8, the side surface of the lower part of the roller shell 6-1 is connected with a lower discharge port 6-8, the lower discharge port 6-8 is blocked by a discharge port plug 13, the middle of the roller lower cover 6-6 is, in an upper positioning sleeve 6-4 of a spiral shaft 6-2, the spiral shaft 6-2 comprises spiral blades with different diameters, a roller chain wheel 6-5 is installed at the lower end of a connecting shaft head 6-6-1, two support plates of a motor support 11 are respectively welded on the outer sides of the middle parts of two support pipes 21, the welding positions of the support plates are matched with the positions of long grooves of a slotted pipe 22, a spiral rolling motor 12 is installed on the motor support 11, a motor connecting chain wheel 9 is installed on the spiral rolling motor 12, the position of the motor chain wheel 9 is matched with that of the roller chain wheel 6-5, the motor chain wheel 9 is connected with the roller chain wheel 6-5 through a chain, and a tensioning ring 6-9 is welded in the middle part of the outer side.

When the lower discharge port 6-8 is used for discharging materials on site, the spiral shaft 6-2 in the spiral roller 6 is replaced by a half spiral shaft 6-10, the upper discharge port 6-7 is blocked by a discharge port plug 13, and the lower discharge port 6-8 is connected with a discharge pipe 19 through a discharge port connector 7 and an outlet clamp 8.

Claims

1. Building secondary structure material loading machine, including spiral drum (6), its characterized in that: the spiral roller (6) is arranged above the movable chassis (10) through the double-T-shaped support, the material receiving hopper (1) is arranged at the feed inlet of the spiral roller (6), and the hoisting machine capable of feeding materials into the material receiving hopper (1) is further arranged through the double-T-shaped support.

2. The building secondary structure feeder of claim 1, wherein: the bottom surface of the material receiving hopper (1) is a front-high rear-low inclined plane, the lower part of the rear end of the material receiving hopper (1) is provided with a hole communicated with the spiral roller (6), the side surface of the upper part of the spiral roller (6) is provided with an upper discharge port (6-7), the discharge port (6-7) is connected with a discharge pipe (19) through a discharge interface (7) and an outlet clamp (8), and materials are conveyed to the discharge pipe (19) through a spiral manner to complete material conveying.

3. The building secondary structure feeder of claim 1, wherein: the movable chassis (10) is rectangular, the two sides of the middle part below the movable chassis (10) are respectively welded with a directional pipe (15), the middle parts of the two sides above the movable chassis (10), namely the upper part of the directional pipe (15), are respectively welded with a vertical channel steel (20), a slotted pipe (22) is welded on the vertical channel steel (20), the two directional pipes (15) and the slotted pipe (22) are respectively provided with a support pipe (21) in a sliding way, the lower part of the movable chassis (10) is connected with a winch (3), the two sides of the upper part of the front part of the movable chassis (10) are respectively welded with a rope guide pipe (18), the upper ends of the two support pipes (21) are respectively welded with an upper long pipe (26), the direction of the upper long pipe (26) is vertical to the connecting line between the two support pipes (21), and the middle part of the upper long pipe (26) is welded, pulley shaft brackets I (31) are respectively welded behind middle lacing wires II (30) of the two upper long pipes (26), pulley shafts I (32) are installed on the two pulley shaft brackets I (31), pulleys I (33) are installed in the middles of the pulley shafts I (32), adjustable pipes (27) are respectively sleeved on the front sections of the two upper long pipes (26), pulley shaft brackets II (34) are respectively welded on the inner sides of the front ends of the adjustable pipes (27), pulley shafts II (35) are installed on the two pulley shaft brackets II (34), pulleys II (36) are installed in the middles of the pulley shafts II (35), pulley frames (37) are respectively welded below the rear portions of the adjustable pipes (27), pulleys (38) are installed on the pulley frames (37), a jacking wire seat (39) is welded behind the pulley frames (37) below the rear portions of the adjustable pipes (27), a jacking wire (40) is installed on the jacking wire seat (39), the rear sections of the two upper long pipes (26) are respectively sleeved with a fixed pipe (28), a top thread seat (39) is respectively welded below the front part of the fixed pipe (28), a top thread (40) is arranged on the top thread seat (39), and a lacing wire I (29) is connected between the two fixed pipes (28).

4. A building secondary structure feeder as claimed in claim 3, characterised in that: the rope guide pipe (18) in the interpolation be equipped with rope guide pipe I (41), rope guide pipe II (42) is being connected perpendicularly at the front end of rope guide pipe I (41), rope guide pipe I (41) and rope guide pipe II (42) junction are porose, staff (43) are being connected in the hole, rope guide cover (44) are being suit on staff (43), the hypomere front side of rope guide pipe II (42) is connected with rope guide wheel seat (45), install rope guide wheel (46) on rope guide wheel seat (45), top wire seat (39) are being welded to the higher authority of rope guide pipe (18), install jackscrew (40) on top wire seat (39).

5. A building secondary structure feeder as claimed in claim 3, characterised in that: the upper sections of the two slotted pipes (22) are respectively welded with a connecting plate (25), a supporting seat (24) is arranged on the connecting plate (25), a lifting roller (23) is arranged between two supporting seats (24), a steel wire rope III (47) is wound on the lifting roller (23), the lower sections of two supporting pipes (21) are respectively welded with the front of a connecting plate I (48-3), the welding positions of two connecting plates I (48-3) are matched with the positions of long grooves of a slotted pipe (22), the rear parts of the two connecting plates I (48-3) are respectively connected with the two ends of a lifting rod (48-2), a lifting ring II (48-5) is welded on the middle of the lifting rod (48-2), the lifting ring II (48-5) is connected with the other end of the steel wire rope III (47), and a wrench (51) is used for moving the lifting roller (23) to enable the two supporting pipes (21) to be lifted upwards.

6. A building secondary structure feeder as claimed in claim 3, characterised in that: the supporting connecting rods (48) are arranged below the two supporting pipes (21), the supporting connecting rods (48) comprise connecting rods (48-1), the upper ends of the connecting rods (48-1) are fixedly connected with connectors (48-4), the lower sections of the connecting rods (48-1) are respectively connected with connecting plates I (48-3), the two connecting plates I (48-3) are respectively connected to the two ends of a lifting rod (48-2), lifting rings II (48-5) are welded to the middle of the lifting rod (48-2), and the lifting rings II (48-5) are connected to the other end of a steel wire rope III (47).

7. The building secondary structure feeder of claim 1, wherein: the automatic feeding device also comprises a feeding hopper (2), wherein the feeding hopper (2) comprises a hopper (2-1), the side face of the hopper (2-1) is in a semicircular shape at the front part and in a rectangular shape at the rear part, fixed shafts (2-5) are respectively welded at the outer sides of the middle parts of the two side faces of the hopper, movable sleeves (2-4) are arranged on the fixed shafts (2-5), movable arms (2-3) are welded on the movable sleeves (2-4), the top ends of the two movable arms (2-3) are welded at the two ends of a lifting rod I (2-2), lifting rings I (2-6) are welded at the upper part of the middle part of the lifting rod I (2-2), sleeves (2-7) are respectively welded at the outer side of the rear part of the hopper (2-1), rotating shafts (2-8) are penetrated in the sleeves (2-7), shaft retaining pieces (2-9) for shafts are, the outer side end of the rotating shaft (2-8) is welded with a clamping plate I (2-10), two guide wheel shafts (2-12) are welded on the clamping plate I (2-10), guide wheels (2-11) are installed on the guide wheel shafts (2-12), clamping plates II (2-13) are installed outside the guide wheels (2-11) and locked by screws, the receiving hopper (1) comprises a receiving dustpan (1-3), a rope passing pipe (1-2) is welded on the middle of the receiving dustpan (1-3), a hinge (1-4) is welded below the middle of the receiving dustpan (1-3), a supporting rod (50) is connected between the two supporting pipes (21), and the hinge (1-4) is connected with the supporting rod (50).

8. The building secondary structure feeder of claim 1, wherein: the feeding hopper (2) is replaced by a feeding tray (49), the feeding tray (49) comprises a tray (49-1),

a lifting lacing wire 49-3 is connected on a tray 49-1, a lifting rod II 49-4 is connected at the top end of the lifting lacing wire 49-3, a lifting ring I2-6 is welded in the middle of the lifting rod II 49-4, a supporting leg 49-2 is arranged below the front end of the tray 49-1, sleeves 2-7 are respectively welded at the outer sides of the two side surfaces of the rear part of the tray 49-1, a rotating shaft 2-8 is penetrated in the sleeves 2-7, the inner side end of the rotating shaft 2-8 is connected with the rotating shaft 2-8 by a baffle plate 2-9, a clamping plate I2-10 is welded at the outer side end of the rotating shaft 2-8, two guide wheel shafts 2-12 are welded on the clamping plate I2-10, the guide wheel shaft (2-12) is provided with a guide wheel (2-11), and the outside of the guide wheel (2-11) is provided with a clamping plate II (2-13) and is locked by screws.

9. The building secondary structure feeder of claim 1, wherein: the spiral roller (6) comprises a roller lower cover (6-6), the upper outer ring of the roller lower cover (6-6) is connected with a roller shell (6-1), the lower part of the roller shell (6-1) is in a conical shape with the upper part of a cylinder being large at the bottom and small at the top, the top end of the upper part of the roller shell (6-1) is connected with a roller upper cover (6-3), the middle of the lower part of the roller upper cover (6-3) is connected with an upper locating sleeve (6-4), the upper side surface of the roller shell (6-1) is connected with an upper discharge hole (6-7), the upper discharge hole (6-7) is connected with a discharge pipe (19) through a discharge interface (7) and an outlet clamp (8), the lower side surface of the roller shell (6-1) is connected with a lower discharge hole (6-8), and the lower discharge hole (6, a connecting shaft head (6-6-1) is arranged in the middle of a lower cover (6-6) of the roller, the upper end of the connecting shaft head (6-6-1) is connected with a screw shaft (6-2), the screw shaft (6-2) is arranged in an upper positioning sleeve (6-4), the screw shaft (6-2) comprises screw blades with different diameters, a roller chain wheel (6-5) is arranged at the lower end of the connecting shaft head (6-6-1), two support plates of a motor support (11) are respectively welded at the outer sides of the middle parts of two support tubes (21), the welding positions of the support plates are matched with the positions of long grooves of a grooved tube (22), a spiral rolling motor (12) is arranged on the motor support (11), a motor connecting chain wheel (9) is arranged on the spiral rolling motor (12), and the position of the motor chain wheel (9) is matched with the roller chain, the motor chain wheel (9) is connected with the roller chain wheel (6-5) by a chain, and the middle part of the outer side of the spiral roller (6) is welded with the tensioning ring (6-9).

10. A building secondary structure feeder as claimed in claim 1 or 9, characterised in that: the upper end of a connecting shaft head (6-6-1) on a lower cover (6-6) of the spiral roller (6) is connected with a semi-spiral shaft (6-10), an upper discharge port (6-7) is blocked by a discharge port plug (13), and a lower discharge port (6-8) is connected with a discharge pipe (19) through a discharge port connector (7) and an outlet clamp (8).