CN219754165U - Steel bar processing shed - Google Patents

Abstract

The utility model discloses a steel bar processing shed which comprises a raw material area, a cutting area, a welding area and a finished product area which are sequentially arranged at intervals, wherein the raw material area is provided with a raw material bin for placing construction materials, the cutting area is used for cutting the construction materials, the welding area is used for welding the cut construction materials, the finished product area is used for stacking the processed construction materials and a transportation assembly, and the transportation assembly comprises a first transportation assembly connected between the raw material area and the cutting area and a second transportation assembly communicated with the cutting area, the welding area and the finished product area. According to the technical scheme, the first conveying assembly is arranged between the raw material area and the cutting area, the second conveying assembly communicated with the cutting area, the welding area and the finished product area is arranged between the cutting area and the finished product area, construction materials are conveyed out of the first conveying assembly, conveyed to the welding area and the finished product area through the cutting area and conveyed to the second conveying assembly, and therefore assembly line of a processing site of the steel bar processing shed is achieved, and processing efficiency of the construction materials is improved.

Description

Steel bar processing shed

Technical Field

The utility model relates to the technical field of building construction, in particular to a steel bar processing shed.

Background

The building construction site can be generally erected with a steel bar processing shed to meet the requirement of nearby processing of building materials in a construction site, however, the existing steel bar processing shed is often complicated in building material processing flow due to unreasonable station arrangement, a large amount of manpower and material resources are wasted, and a serious person drags a construction period.

Disclosure of Invention

The utility model mainly aims to provide a steel bar machining shed and aims to provide a steel bar machining shed structure with reasonable station arrangement and high cooperation efficiency among stations.

In order to achieve the above object, the present utility model provides a rebar processing shed comprising:

the device comprises a raw material area, a cutting area, a welding area and a finished product area which are sequentially arranged at intervals, wherein the raw material area is provided with a raw material bin for placing construction materials, the cutting area is used for cutting the construction materials, the welding area is used for welding the cut construction materials, and the finished product area is used for stacking the construction materials after processing; the method comprises the steps of,

and the conveying assembly comprises a first conveying assembly connected between the raw material area and the cutting area and a second conveying assembly communicated with the cutting area, the welding area and the finished product area.

Optionally, the raw material bin is provided with a storage cavity, a blanking port is arranged at the bottom of the storage cavity, and the first transportation assembly is arranged corresponding to the blanking port;

wherein the first transport assembly comprises:

the belt pulley assembly comprises two belt pulleys and a belt, wherein the two belt pulleys are arranged at intervals along the raw material zone to the cutting zone, and the belt is wound on the two belt pulleys;

and the driving motor is provided with a rotating shaft, and the driving motor is connected with at least one of the two belt pulleys through the rotating shaft.

Optionally, the first transport assembly further comprises:

the limiting plate is arranged at one end, far away from the raw material bin, of the belt wheel assembly;

the pressure sensor is arranged on the side of the limiting plate opposite to the belt wheel assembly;

and the circuit board assembly is electrically connected with the pressure sensor and the driving motor.

Optionally, the rebar machining shed further comprises a buffer assembly to provide a buffer for movement of the construction material on the first transportation assembly;

the cushioning assembly includes:

the base plate is used for being fixed on the ground;

the buffer plate is arranged above the base plate and is used for being in contact with the first conveying assembly;

and a buffer part arranged between the substrate and the buffer plate.

Optionally, the buffer part includes a buffer spring, one end of the buffer spring is connected to the upper surface of the substrate, and the other end of the buffer spring is connected to the buffer plate.

Optionally, the steel bar processing shed further comprises a clamping tool, wherein the clamping tool is arranged in the cutting area and used for clamping construction materials for auxiliary cutting;

the clamping tool comprises:

the cutting table comprises a cutting plate and two supporting legs which are arranged at two sides of the cutting plate at intervals along the length direction of the cutting plate, wherein the two supporting legs are used for supporting the cutting plate on the ground, and the cutting plate is provided with a long hole extending along the length direction of the cutting plate;

the positioning block is arranged on the cutting plate and is provided with a positioning groove which is adaptive to the shape of the construction material;

the locking block is arranged corresponding to the positioning block and provided with a movement stroke close to and far away from the positioning block, and a through hole is arranged at the position of the locking block relative to the long hole;

the screw locking structure comprises a bolt and a nut which are matched with each other, the bolt penetrates through the through hole from top to bottom and stretches into the long hole, and the nut is used for being matched with the bolt to lock the locking block on the cutting plate.

Optionally, the clamping tool further comprises a guide structure, wherein the guide structure comprises a sliding block and a guide rail which are matched with each other;

the guide rail is arranged on the cutting plate along the length direction of the cutting plate;

the sliding block is connected with the bottom of the locking block and can drive the locking block to move along the direction of the guide rail.

Optionally, the positioning block is detachably connected to the cutting plate;

the locating blocks are arranged in a plurality, and different locating blocks are provided with different locating grooves so as to be suitable for different construction materials.

Optionally, a plurality of cutting holes are arranged on the cutting plate at intervals along the width direction of the cutting plate.

Optionally, the second transporting assembly includes a plurality of manipulators arranged at intervals along the cutting zone to finishing zone direction.

According to the technical scheme, the steel bar processing shed comprises a raw material area, a cutting area, a welding area and a finished product area which are sequentially distributed at intervals, wherein a first conveying assembly is arranged between the raw material area and the cutting area, a second conveying assembly which is communicated with the cutting area, the welding area and the finished product area is arranged between the cutting area, the welding area and the finished product area, construction materials are conveyed out of the first conveying assembly, conveyed to the welding area and the finished product area through the cutting area and conveyed to the second conveying assembly, and therefore pipelining of a steel bar processing shed processing site is achieved, and processing efficiency of the construction materials is improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of an embodiment of a station layout of a rebar machining shed according to the present utility model;

FIG. 2 is a schematic view of the structure of the raw material storage bin and the first transport assembly of FIG. 1;

fig. 3 is a schematic structural diagram of the clamping tool in fig. 1.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

The building construction site can be generally erected with a steel bar processing shed to meet the requirement of nearby processing of building materials in a construction site, however, the existing steel bar processing shed is often complicated in building material processing flow due to unreasonable station arrangement, a large amount of manpower and material resources are wasted, and a serious person drags a construction period.

In order to solve the above problems, the present utility model provides a rebar processing shed, and aims to provide a rebar processing shed structure with reasonable station layout and high cooperation efficiency between stations, wherein fig. 1 to 3 are schematic structural diagrams of an embodiment of station layout of the rebar processing shed provided by the present utility model.

Referring to fig. 1 and 2, the steel bar processing shed includes a raw material area 7, a cutting area 8, a welding area 9 and a finished product area 10 which are sequentially arranged at intervals, the raw material area 7 is provided with a raw material bin 1 for placing construction materials, the cutting area 8 is used for cutting the construction materials, the welding area 9 is used for welding the construction materials after cutting, the finished product area 10 is used for stacking the construction materials after processing and a transportation assembly 2, and the transportation assembly 2 comprises a first transportation assembly 212 connected between the raw material area 7 and the cutting area 8 and a second transportation assembly 2 communicated with the cutting area 8, the welding area 9 and the finished product area 10.

According to the technical scheme, the steel bar processing shed comprises a raw material area 7, a cutting area 8, a welding area 9 and a finished product area 10 which are sequentially distributed at intervals, wherein a first conveying assembly 212 is arranged between the raw material area 7 and the cutting area 8, a second conveying assembly 2 which is communicated with the cutting area 8, the welding area 9 and the finished product area 10 is arranged between the cutting area 8, the welding area 9 and the finished product area 10, construction materials are conveyed out of the first conveying assembly 212, conveyed to the welding area 9 and the finished product area 10 through the cutting area 8 through the second conveying assembly 2, so that the pipelining of a processing site of the steel bar processing shed is realized, and the processing efficiency of the construction materials is improved.

In order to realize the transportation of the construction material between the raw material bin 1 of the raw material zone 7 and the cutting zone 8, please refer to fig. 1, in an embodiment of the present utility model, the raw material bin 1 has a storage cavity 11, a blanking port 111 is disposed at the bottom of the storage cavity 11, and the first transportation component 212 is disposed corresponding to the blanking port 111; wherein the first transport assembly 212 comprises: a pulley assembly 211 and a drive motor 212, said pulley assembly 211 comprising two pulleys 2111 spaced along said stock zone 7 to cutting zone 8, and a belt 2112 wound around two of said pulleys 2111, said drive motor 212 having a rotation axis through which said drive motor 212 is connected to at least one of said two pulleys 2111.

In the above embodiment, the construction material falls onto the pulley assembly 211 from the raw material bin 1 through the blanking port 111, the pulley assembly 211 may be driven by the driving motor 212 to move forward, and along with the forward movement of the pulley assembly 211, the construction material in the raw material bin 1 falls onto the pulley assembly 211 from the blanking port 111, so as to achieve the purpose of conveying the construction material from the raw material bin 1 to the cutting area 8.

The first transporting assembly 212 further comprises a limiting plate 213, a pressure sensor 214 and a circuit board assembly, the limiting plate 213 is arranged at one end, away from the raw material bin 1, of the pulley assembly 211, the pressure sensor 214 is arranged at the side, opposite to the pulley assembly 211, of the limiting plate 213, the circuit board assembly is electrically connected with the pressure sensor 214 and the driving motor 212, in this embodiment, the limiting plate 213 is arranged at the transporting end of the pulley assembly 211, when the construction material is transported by the pulley assembly 211 and approaches the transporting end of the pulley assembly 211, the limiting plate 213 limits the construction material, and prevents the construction material from moving forwards continuously, meanwhile, the construction material contacts with the pressure sensor 214 arranged on the limiting plate 213, so that the pressure sensor 214 sends an electric signal to the circuit board assembly, the driving motor 212 stops transporting the construction material detected by the pulley assembly 211, and waits for manually transporting the construction material from the pulley assembly 211, and when the construction material is transported, the driving motor 212 continues to move until the construction material continuously abuts against the limiting plate 213.

It will be appreciated that when the construction material falls down from the blanking port 111, the construction material impacts the first transport assembly 212, and therefore, in an embodiment of the present utility model, the reinforcing bar processing shed further includes a buffer assembly 3 for providing a buffer for the movement of the construction material on the first transport assembly 212, the buffer assembly 3 includes a base plate 31, a buffer plate 32, and a buffer 33, the base plate 31 is fixed on the ground, the buffer plate 32 is disposed above the base plate 31 for contacting the first transport assembly 212, the buffer 33 is disposed between the base plate 31 and the buffer plate 32, and when the construction material falls down, the first transport assembly 212 pushes the buffer plate 32 to move down under the downward impact force of the construction material, and compresses the buffer 33, so as to convert the kinetic energy of the construction material into the mechanical energy of the buffer 33 and release the mechanical energy, thereby achieving the purpose of buffering the impact of the construction material and protecting the first transport assembly.

The buffer portion 33 may be a hydraulic buffer or a buffer spring 33a, and in view of cost, in an embodiment of the present utility model, the buffer portion 33 includes a buffer spring 33a, one end of the buffer spring 33a is connected to the upper surface of the base plate 31, and the other end is connected to the buffer plate 32, and the impact kinetic energy of the construction material can be converted into elastic potential energy of the spring by the buffer spring 33a, so as to buffer the first transport assembly 212.

After the construction material is manually carried down from the first conveying assembly 212, the construction material enters a cutting area 8 for cutting, a cutting tool is arranged in the cutting area 8 to assist the manual cutting of the construction material, specifically, referring to fig. 3, in an embodiment of the present utility model, the steel bar processing shed further comprises a clamping tool 4, and the clamping tool 4 is arranged in the cutting area 8 to clamp the construction material for assisting in cutting; the clamping tool 4 comprises a cutting table 41, a positioning block 42, a locking block 43 and a threaded locking structure, wherein the cutting table 41 comprises a cutting plate 411 and two supporting legs 412 which are arranged on two sides of the cutting plate 411 at intervals along the length direction of the cutting plate 411, the two supporting legs 412 are used for supporting the cutting plate 411 on the ground, a long hole 4111 which extends along the length direction of the cutting plate 411 is formed in the cutting plate 411, the positioning block 42 is arranged on the cutting plate 411, the positioning block 42 is formed with a positioning groove 421 which is matched with the shape of a construction material, the locking block 43 is arranged corresponding to the positioning block 42 and has a movement stroke which is close to and far away from the positioning block 42, the position of the locking block 43 relative to the long hole 4111 is provided with a through hole 431, the threaded locking structure comprises a bolt and a nut which are matched with each other, the bolt penetrates through the through hole 431 from top to bottom and stretches into the long hole 4111, and the nut is used for locking the locking block 43 and the cutting plate 411 by matching the bolt.

In the above embodiment, the cutting table 41 includes the cutting plate 411 and two supporting legs 412, the cutting plate 411 is suspended and supported on the supporting surface by the two supporting legs 412, and for the specific type of the supporting legs 412, the cutting plate 411 may be suspended and supported on the supporting surface, the supporting plate is provided with the positioning block 42, the positioning block 42 is provided with the positioning groove 421 adapted to the construction material, the construction material is placed on the cutting plate 411, and the positioning groove 421 is used for providing limitation for the construction material. The positioning groove 421 side of the positioning block 42 is correspondingly provided with a locking block 43 for clamping construction materials together with the positioning block 42, specifically, along the advancing direction of the locking block 43, the cutting plate 411 is provided with a long hole 4111, the locking block 43 is correspondingly provided with a through hole 431, the clamping fixture 4 further comprises a threaded locking structure, when the locking block 43 moves to a preset position, an operator can manually lock the locking block 43 on the cutting plate 411 below the cutting plate 411 through the threaded locking structure, so that the purpose of clamping construction materials is achieved.

In order to enable the locking block 43 to move along a preset track, in an embodiment of the present utility model, the clamping fixture 4 further includes a guiding structure, the guiding structure includes a slider and a guide rail 44 that are matched with each other, the guide rail 44 is disposed on the cutting plate 411 along the length direction of the cutting plate 411, the slider is connected to the bottom of the locking block 43 and can drive the locking block 43 to move along the direction of the guide rail 44, so that guiding is provided for the locking block 43 by the guide rail 44, so that the locking block 43 can move along the preset track.

In order to make the clamping fixture 4 adaptable to more types of construction materials, in an embodiment of the present utility model, the positioning blocks 42 are detachably connected to the cutting plate 411, the positioning blocks 42 are provided in a plurality, and different positioning blocks 42 have different positioning slots 421 to adapt to different construction materials, so that the clamping fixture 4 can clamp more construction materials, and the applicability of the clamping fixture 4 is improved.

In order to facilitate the cutting of the cutter on the clamping tool 4, in an embodiment of the present utility model, a plurality of cutting holes 4112 are formed on the cutting plate 411 at intervals along the width direction of the cutting plate 411, so as to provide a space for avoiding the cutter cutting, and prevent the cutter from cutting the cutting plate 411 while cutting the building material.

After the construction material is cut, the construction material enters the welding area 9 to be welded, and the construction material after the welding is finished enters the finished product area 10, so that the welding is convenient, in one embodiment of the utility model, the second transportation assembly 2 comprises a plurality of manipulators 22 which are distributed at intervals along the direction from the cutting area 8 to the finished product area 10, when the construction material is finished in the cutting area 8, the construction material is conveyed by the manipulators 22, and the construction material is conveyed and welded between the cutting area 8 and the welding area 9, so that the labor cost is saved; for construction materials inconvenient to carry by the large manipulator 22, the belt wheel assembly 211 can be adopted for transportation, and the manipulator 22 can be used for welding the construction detection, so that the utility model is not limited to the method.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the description of the present utility model and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the utility model.

Claims (10)

1. The steel bar machining shed is characterized by comprising a raw material area, a cutting area, a welding area and a finished product area which are sequentially arranged at intervals, wherein the raw material area is provided with a raw material bin for placing construction materials, the cutting area is used for cutting the construction materials, the welding area is used for welding the cut construction materials, and the finished product area is used for piling the construction materials after machining; the method comprises the steps of,

and the conveying assembly comprises a first conveying assembly connected between the raw material area and the cutting area and a second conveying assembly communicated with the cutting area, the welding area and the finished product area.

2. The rebar machining shed as in claim 1, wherein the raw stock bin has a storage cavity, wherein a blanking port is provided at a bottom of the storage cavity, and wherein the first transport assembly is provided corresponding to the blanking port;

wherein the first transport assembly comprises:

the belt pulley assembly comprises two belt pulleys and a belt, wherein the two belt pulleys are arranged at intervals along the raw material zone to the cutting zone, and the belt is wound on the two belt pulleys;

and the driving motor is provided with a rotating shaft, and the driving motor is connected with at least one of the two belt pulleys through the rotating shaft.

3. The rebar machining shed of claim 2, wherein the first transport assembly further comprises:

the limiting plate is arranged at one end, far away from the raw material bin, of the belt wheel assembly;

the pressure sensor is arranged on the side of the limiting plate opposite to the belt wheel assembly;

and the circuit board assembly is electrically connected with the pressure sensor and the driving motor.

4. The rebar machining booth of claim 1, further comprising a buffer assembly to provide a buffer for movement of construction material on the first transport assembly;

the cushioning assembly includes:

the base plate is used for being fixed on the ground;

the buffer plate is arranged above the base plate and is used for being in contact with the first conveying assembly;

and a buffer part arranged between the substrate and the buffer plate.

5. The rebar processing shed of claim 4, wherein the buffer comprises a buffer spring having one end connected to the upper surface of the base and the other end connected to the buffer plate.

6. The rebar machining booth of claim 1, further comprising a clamping fixture disposed within the cutting zone for clamping a work material to assist in cutting;

the clamping tool comprises:

the cutting table comprises a cutting plate and two supporting legs which are arranged at two sides of the cutting plate at intervals along the length direction of the cutting plate, wherein the two supporting legs are used for supporting the cutting plate on the ground, and the cutting plate is provided with a long hole extending along the length direction of the cutting plate;

the positioning block is arranged on the cutting plate and is provided with a positioning groove which is adaptive to the shape of the construction material;

the locking block is arranged corresponding to the positioning block and provided with a movement stroke close to and far away from the positioning block, and a through hole is arranged at the position of the locking block relative to the long hole;

the screw locking structure comprises a bolt and a nut which are matched with each other, the bolt penetrates through the through hole from top to bottom and stretches into the long hole, and the nut is used for being matched with the bolt to lock the locking block on the cutting plate.

7. The rebar machining shed of claim 6, wherein the clamping fixture further comprises a guide structure comprising a slider and a rail that cooperate with each other;

the guide rail is arranged on the cutting plate along the length direction of the cutting plate;

the sliding block is connected with the bottom of the locking block and can drive the locking block to move along the direction of the guide rail.

8. The rebar machining booth of claim 6, wherein the locating block is removably attached to the cutting plate;

the locating blocks are arranged in a plurality, and different locating blocks are provided with different locating grooves so as to be suitable for different construction materials.

9. The rebar machining booth of claim 6, wherein a plurality of cutting holes are spaced apart along the width of the cutting plate.

10. The rebar machining shed of claim 1, wherein the second transport assembly includes a plurality of manipulators spaced along the cut-out area to finish area direction.