阅读说明：本技术 一种建筑用高强度抗震钢材制备设备 (High-strength anti-seismic steel preparation equipment for building ) 是由 李用记 于 2021-07-16 设计创作，主要内容包括：本发明公开了一种建筑用高强度抗震钢材制备设备,其结构包括底板、支撑架、输送架、切割刀架,支撑架焊接于底板的上表面位置,切割刀架安装于底板的上端位置,输送架与底板的上端活动卡合,通过高强度抗震钢筋对切割刀片产生的反推力,能够使切割刀片推动滑动杆沿着罩体向上滑动收缩,从而使切割刀片的刀刃能够卡入清理机构的内部,故而使清理板能够在切割刀片高速转动时对切割刀片的刀刃表面附着的钢屑进行打磨去除,通过切割刀片对高强度抗震钢筋切割完成时,弹片在切割刀片的配合下沿着罩体向下快速复位与罩体内部撞击产生的振动,能够使振动块对内置腔的内壁产生撞击,从而能够使清理机构内侧附着的粉末掉落。(The invention discloses a device for preparing high-strength anti-seismic steel for buildings, which structurally comprises a bottom plate, a supporting frame, a conveying frame and a cutting knife rest, wherein the supporting frame is welded at the upper surface of the bottom plate, the cutting knife rest is arranged at the upper end of the bottom plate, the conveying frame is movably clamped with the upper end of the bottom plate, through the reverse thrust generated by a high-strength anti-seismic steel bar to a cutting blade, the cutting blade can push a sliding rod to slide upwards along a cover body for shrinkage, so that the cutting edge of the cutting blade can be clamped into a cleaning mechanism, the cleaning plate can polish and remove steel scraps attached to the surface of the cutting edge of the cutting blade when the cutting blade rotates at a high speed, when the cutting of the high-strength anti-seismic steel bar is finished, a spring plate is quickly reset downwards along the cover body under the cooperation of the cutting blade and vibrates with the interior of the cover body due to impact, so that a vibrating block can generate impact on the inner wall of a built-in cavity, thereby enabling the powder attached to the inside of the cleaning mechanism to fall off.)

1. The utility model provides a high strength antidetonation steel preparation equipment for building, its structure includes bottom plate (1), support frame (2), carriage (3), cutting knife rest (4), support frame (2) weld in the upper surface position of bottom plate (1), cutting knife rest (4) are installed in the upper end position of bottom plate (1), its characterized in that: the conveying frame (3) is movably clamped with the upper end of the bottom plate (1);

carriage (3) include lifter (31), removal frame (32), cutting blade (33), safety cover (34), the upper end of lifter (31) is laminated with the inner wall upper end that removes frame (32), the center and the safety cover (34) activity block of cutting blade (33), the bottom position in lifter (31) is installed in safety cover (34).

2. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 1, wherein: the protective cover (34) comprises a spring piece (a1), a cover body (a2) and a sliding rod (a3), wherein the spring piece (a1) is installed between the upper end of the inner wall of the cover body (a2) and the top of the sliding rod (a3), and the sliding rod (a3) is movably clamped with the inner wall of the cover body (a 2).

3. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 2, wherein: the cover body (a2) comprises a cleaning mechanism (a21), a welding piece (a22) and a plate surface (a23), wherein the cleaning mechanism (a21) is welded to the inner side position of the plate surface (a23) through the welding piece (a 22).

4. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 3, wherein: clearance mechanism (a21) is including clearance board (b1), frame (b2), boosting strip (b3), the inside activity block of clearance board (b1) and frame (b2), boosting strip (b3) are installed between the inner wall of clearance board (b1) and frame (b 2).

5. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 3, wherein: the plate surface (a23) comprises a built-in cavity (c1), a bearing plate (c2) and a vibrating block (c3), the built-in cavity (c1) is embedded in the inner position of the bearing plate (c2), and the vibrating block (c3) is in clearance fit with the inner portion of the built-in cavity (c 1).

6. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 5, wherein: the vibrating block (c3) comprises a contraction plate (c31), a reverse thrust piece (c32) and a middle fixing plate (c33), wherein the contraction plate (c31) is movably clamped with the inside of the reverse thrust piece (c32), and the middle fixing plate (c33) is installed between the inner side of the contraction plate (c31) and the outer side of the reverse thrust piece (c 32).

7. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 6, wherein: the contraction plate (c31) comprises an elastic strip (d1), an impact block (d2), a stress plate (d3) and a transition plate (d4), wherein the elastic strip (d1) is installed between the upper end of the impact block (d2) and the upper end of the inner wall of the stress plate (d3), and the bottom of the transition plate (d4) is attached to the upper surface of the stress plate (d 3).

8. The apparatus for manufacturing high-strength anti-seismic steel for construction according to claim 5, wherein: the bearing plate (c2) comprises a swinging plate (e1), a reset piece (e2) and a combination plate (e3), the swinging plate (e1) is hinged with the inner side of the combination plate (e3), and the reset piece (e2) is installed between the inner side of the swinging plate (e1) and the inner wall of the combination plate (e 3).

Technical Field

The invention relates to the technical field of fine steel preparation, in particular to high-strength anti-seismic steel preparation equipment for buildings.

Background

The present inventors found based on the above description that the present high-strength anti-seismic steel bar preparation equipment for building mainly has the following disadvantages, for example:

because cutting blade of machine is cut off in preparation of high strength antidetonation reinforcing bar for building can produce the spark that splashes when cutting the reinforcing bar to the spark touches the removal of cutting knife rest and puts up the inboard rebound that then takes place easily, thereby makes the spark can reverse fall on the cutting blade, and can condense into the steel fillings after the cooling, long-time accumulation then can make cutting blade the not sharp condition of cutting edge appear.

Disclosure of Invention

Aiming at the problems, the invention provides a preparation device of high-strength anti-seismic steel for buildings.

In order to achieve the purpose, the invention is realized by the following technical scheme: the high-strength anti-seismic steel preparation equipment for the building structurally comprises a bottom plate, a support frame, a conveying frame and a cutting knife rest, wherein the support frame is welded on the upper surface of the bottom plate, the cutting knife rest is installed at the upper end of the bottom plate, and the conveying frame is movably clamped with the upper end of the bottom plate; the conveying frame comprises a lifting rod, a moving frame, a cutting blade and a protective cover, the upper end of the lifting rod is attached to the upper end of the inner wall of the moving frame, the center of the cutting blade is movably clamped with the protective cover, and the protective cover is installed at the bottom of the lifting rod.

As a further optimization of the invention, the protective cover comprises an elastic sheet, a cover body and a sliding rod, the elastic sheet is arranged between the upper end of the inner wall of the cover body and the top of the sliding rod, the sliding rod is movably clamped with the inner wall of the cover body, and the cutting blade can push the sliding rod to slide upwards and contract through the reverse thrust generated by the steel bar on the cutting blade.

As a further optimization of the invention, the cover body comprises two cleaning mechanisms, two welding sheets and a plate surface, wherein the cleaning mechanisms are welded at the inner side positions of the plate surface through the welding sheets, and the cleaning mechanisms are uniformly and symmetrically distributed on the left side and the right side of the inner wall of the plate surface.

As a further optimization of the invention, the cleaning mechanism comprises a cleaning plate, a frame and a boosting strip, the cleaning plate is movably clamped with the inside of the frame, the boosting strip is arranged between the cleaning plate and the inner wall of the frame, and the cleaning plate is made of a grinding stone.

As a further optimization of the invention, the board surface comprises a built-in cavity, a bearing plate and two vibrating blocks, the built-in cavity is embedded in the bearing plate, the vibrating blocks are in clearance fit with the internal part of the built-in cavity, and the vibrating blocks are uniformly and symmetrically distributed in the bearing plate.

As a further optimization of the invention, the vibrating block comprises a contraction plate, a reverse thrust piece and four middle fixing plates, wherein the contraction plate is movably clamped with the inner part of the reverse thrust piece, the middle fixing plates are arranged between the inner side of the contraction plate and the outer side of the reverse thrust piece, and the contraction plate is uniformly distributed on the reverse thrust piece in a circular shape.

As a further optimization of the invention, the contraction plate comprises an elastic strip, an impact block, a stress plate and a transition plate, the elastic strip is arranged between the upper end of the impact block and the upper end of the inner wall of the stress plate, the bottom of the transition plate is attached to the upper surface of the stress plate, and the impact block is made of alloy steel with high density.

As a further optimization of the present invention, the receiving plate includes a swinging plate, two resetting plates and a combining plate, the swinging plate is hinged to the inner side of the combining plate, the resetting plates are installed between the inner side of the swinging plate and the inner wall of the combining plate, and the swinging plates are uniformly and symmetrically distributed on the inner wall of the combining plate.

The invention has the following beneficial effects:

1. through the thrust reversal of high strength antidetonation reinforcing bar to cutting blade production, can make cutting blade promote the slide bar and upwards slide the shrink along the cover body, thereby make the cutting edge of cutting blade can block the inside of going into clearance mechanism, the accessible steel fillings of cutting blade surface that make the clearance board can be to cutting blade when cutting blade rotates at a high speed are polished and are got rid of, effectual avoided can be cooled off into the steel fillings by the spark of the inboard rebound of carriage and attach to the cutting edge surface of cutting blade, long-time accumulation then can make the condition that no longer sharp appears in the cutting edge of cutting blade.

2. When accomplishing the cutting of high strength antidetonation reinforcing bar through cutting blade, the shell fragment can make the vibrating mass produce the striking to the inner wall in built-in chamber along the vibration that cover body inside striking produced downwards quick reset under cutting blade's cooperation, and the built-in chamber of rethread will vibrate the transmission to accept on the board to can make the inboard adnexed powder of clearance mechanism drop, the effectual condition of avoiding clearance mechanism inner wall long-time accumulation steel fillings powder of polishing.

Drawings

FIG. 1 is a schematic structural view of a high-strength anti-seismic steel material manufacturing apparatus for a building according to the present invention.

Fig. 2 is a front half-section structural schematic diagram of the conveying frame of the invention.

Fig. 3 is a front half-section structural diagram of the protective cover of the present invention.

Fig. 4 is a schematic structural diagram of a front half section and a cleaning mechanism of the cover body.

FIG. 5 is a schematic top view of the cleaning mechanism of the present invention.

FIG. 6 is a schematic structural view of a front half section of a plate surface according to the present invention.

FIG. 7 is a front half-section structural diagram of the vibrating mass of the present invention.

FIG. 8 is a front half-section schematic view of a shrink sheet according to the present invention.

FIG. 9 is a front half-sectional view of the receiving plate of the present invention.

In the figure: the device comprises a bottom plate-1, a support frame-2, a conveying frame-3, a cutting knife rest-4, a lifting rod-31, a moving frame-32, a cutting blade-33, a protective cover-34, an elastic sheet-a 1, a cover body-a 2, a sliding rod-a 3, a cleaning mechanism-a 21, a welding sheet-a 22, a plate surface-a 23, a cleaning plate-b 1, a frame-b 2, a boosting strip-b 3, an internal cavity-c 1, a bearing plate-c 2, a vibrating block-c 3, a contraction plate-c 31, a reverse pushing sheet-c 32, a middle fixing plate-c 33, an elastic strip-d 1, an impact block-d 2, a stress plate-d 3, a transition plate-d 4, a swinging plate-e 1, a resetting sheet-e 2 and a combination plate-e 3.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-5:

the invention provides a high-strength anti-seismic steel preparation device for buildings, which structurally comprises a bottom plate 1, a support frame 2, a conveying frame 3 and a cutting knife rest 4, wherein the support frame 2 is welded on the upper surface of the bottom plate 1, the cutting knife rest 4 is installed at the upper end of the bottom plate 1, and the conveying frame 3 is movably clamped with the upper end of the bottom plate 1; the conveying frame 3 comprises a lifting rod 31, a moving frame 32, a cutting blade 33 and a protective cover 34, the upper end of the lifting rod 31 is attached to the upper end of the inner wall of the moving frame 32, the center of the cutting blade 33 is movably clamped with the protective cover 34, and the protective cover 34 is installed at the bottom position of the lifting rod 31.

The protective cover 34 comprises a spring sheet a1, a cover body a2 and a sliding rod a3, wherein the spring sheet a1 is installed between the upper end of the inner wall of the cover body a2 and the top of the sliding rod a3, the sliding rod a3 is movably clamped with the inner wall of the cover body a2, the cutting blade 33 can push the sliding rod a3 to slide upwards and retract through the reverse thrust of the steel bars on the cutting blade 33, and the spring sheet a1 can match the weight of the cutting blade 33 to slide downwards along the cover body a2 when the reverse thrust of the steel bars is lost.

Wherein, cover body a2 includes clearance mechanism a21, soldering piece a22, face a23, clearance mechanism a21 welds the inboard position in face a23 through soldering piece a22, clearance mechanism a21 is equipped with two, and even the inner wall left and right sides at face a23 is the symmetric distribution to make the object that rises can stretch into inside clearance mechanism a21, so make clearance mechanism a21 can clear away the adnexed steel fillings on the object.

Wherein, clearance mechanism a21 includes clearance board b1, frame b2, boosting strip b3, clearance board b1 and frame b 2's inside activity block, boosting strip b3 installs between clearance board b1 and frame b 2's inner wall, clearance board b1 adopts the stone material of polishing, and through the continuous thrust of boosting strip b3 to clearance board b1 production, can make the inboard of clearance board b1 can thoroughly polish the clearance to the remaining steel cuttings on object surface.

The detailed use method and action of the embodiment are as follows:

in the invention, the conveying frame 3 is adjusted to a designated position by sliding back and forth along the bottom plate 1, the lifting rod 31 pushes the protective cover 34 to cut the high-strength anti-seismic steel bars conveyed by the cutting knife rest 4 downwards, and the cutting blade 33 can push the sliding rod a3 to slide upwards along the cover body a2 by the reverse thrust generated by the high-strength anti-seismic steel bars on the cutting blade 33, so that the cutting edge of the cutting blade 33 can be clamped into the cleaning mechanism a21, and the cleaning plate b1 can slide outwards along the frame b2 by the thrust generated by the boosting bar b3 on the cleaning plate b1, so that the cleaning plate b1 can be attached to the cutting edge surface of the cutting blade 33, the cleaning plate b1 can polish and remove steel scraps attached to the cutting edge surface of the cutting blade 33 when the cutting blade 33 rotates at high speed, and the phenomenon that the steel scraps attached to the cutting edge surface of the cutting blade 33 can be cooled by the sparks rebounded on the inner side of the conveying frame 3 can be effectively avoided, the long term accumulation may cause the edge of the cutting blade 33 to be no longer sharpened.

Example 2

As shown in fig. 6-9:

the plate surface a23 comprises an internal cavity c1, a bearing plate c2 and a vibrating block c3, the internal cavity c1 is embedded in the bearing plate c2, the vibrating block c3 is in clearance fit with the internal cavity c1, two vibrating blocks c3 are arranged and are uniformly and symmetrically distributed in the bearing plate c2, the vibrating block c3 can slide up and down along the internal cavity c1 by means of mechanism reset to generate vibration, so that the vibrating block c3 can generate impact vibration on the inner wall of the internal cavity c1 and then transmit the vibration to the bearing plate c2 through the internal cavity c 1.

The vibrating block c3 includes a contracting plate c31, a reverse pushing piece c32 and a middle fixing plate c33, the contracting plate c31 is movably engaged with the inside of the reverse pushing piece c32, the middle fixing plate c33 is installed between the inner side of the contracting plate c31 and the outer side of the reverse pushing piece c32, four contracting plates c31 are uniformly distributed on the reverse pushing piece c32 in a circular shape, the contracting plate c31 can be contracted inwards along the reverse pushing piece c32 by the reverse pushing force generated by the inner wall of the object on the contracting plate c31, and the contracting plate c31 can be extended outwards along the reverse pushing piece c32 by the reverse pushing force generated by the middle fixing plate c33 on the contracting plate c31, so that the reverse pushing piece c32 can rebound inside the object for multiple times under the cooperation of the contracting plate c 31.

The contraction plate c31 comprises an elastic strip d1, an impact block d2, a stress plate d3 and a transition plate d4, wherein the elastic strip d1 is installed between the upper end of the impact block d2 and the upper end of the inner wall of the stress plate d3, the bottom of the transition plate d4 is attached to the upper surface of the stress plate d3, the impact block d2 is made of alloy steel with high density, and the impact block d2 can slide back and forth along the inner wall of the stress plate d3 in cooperation with the elastic strip d1 through inertia force generated by mechanism extension.

The bearing plate c2 comprises a swinging plate e1, a reset piece e2 and a combination plate e3, the swinging plate e1 is hinged to the inner side of the combination plate e3, the reset piece e2 is installed between the inner side of the swinging plate e1 and the inner wall of the combination plate e3, two swinging plates e1 are arranged, the two swinging plates e1 are uniformly and symmetrically distributed on the inner wall of the combination plate e3, and the swinging plates e1 can swing towards the middle part along the combination plate e3 by means of downward sliding of a mechanism until impact vibration is generated by the mechanism and the inner wall of the combination plate e3, so that the swinging plate e1 can swing outwards along the combination plate e 3.

The detailed use method and action of the embodiment are as follows:

in the invention, when the cleaning mechanism a21 cleans and removes the steel scraps on the cutting edge of the cutting blade 33, powder generated by the grinding steel scraps is easy to adhere to the inner side of the cleaning mechanism a21, if the cleaning mechanism is not cleaned in time, the grinding and removing effect of the cleaning plate b1 on the steel scraps adhering to the surface of the cutting edge is easy to be reduced, when the cutting blade 33 finishes cutting the high-strength anti-seismic steel bars, the elastic sheet a1 is quickly reset along the cover body a2 under the coordination of the cutting blade 33 and is impacted with the inner part of the cover body a2, the vibrating block c3 can generate impact on the inner wall of the built-in cavity c1, and the back thrust generated on the shrinking plate c31 by the inner wall of the built-in cavity c1 can enable the shrinking plate c31 to shrink inwards along the back thrust sheet c32, and the middle fixing plate c33 can quickly push the a31 to reset, so that the vibrating block c3 can slide up and down on the inner wall of the built-in cavity c1 for multiple times and further vibrate the inertia force generated by the block c3, the impact block d2 can generate impact vibration on the inner wall of the stress plate d3 under the coordination of the elastic strip d1, so that the stress plate d3 can enhance the frequency of vibration of the built-in cavity c1, and then the vibration is transmitted to the bearing plate c2 through the built-in cavity c1, so that powder attached to the inner side of the cleaning mechanism a21 can fall off, and the swing plate e1 can swing outwards along the combination plate e3 to reset through the vibration generated by the collision of the sliding rod a3 sliding down and the inner wall of the cover body a2, so that the powder attached to the outer side of the swing plate e1 can fall off, and the condition that steel scraps are accumulated on the inner wall of the cleaning mechanism a21 for a long time to polish the powder is effectively avoided.

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