CN113210535A - Cement panel processing equipment is consolidated to reinforcing bar for civil construction - Google Patents

Abstract

The invention relates to a processing device for a reinforced cement plate, in particular to a processing device for a reinforced cement plate for a civil construction, which comprises a transmission linkage mechanism and a cutting linkage mechanism, wherein the device can transversely transmit a reinforcing steel bar into a cavity of a cement plate grinding tool, the device can transversely transmit the plate and then enter and exit cement into the cement plate grinding tool, the device can longitudinally transmit the reinforcing steel bar into the cavity of the cement plate grinding tool after entering and exiting the cement, the device can cut the transmitted reinforcing steel bar after the cement is solidified, the device can output the reinforced cement plate, and the transmission linkage mechanism is connected with the cutting linkage mechanism.

Description

Cement panel processing equipment is consolidated to reinforcing bar for civil construction

Technical Field

The invention relates to a processing device for a reinforced cement plate, in particular to a processing device for a reinforced cement plate for a civil construction.

Background

In the panel that civil construction used, often need give cement panel reinforcement with the reinforcing bar, this work can not independently be accomplished to most equipment now, and needs more personnel to cooperate when accomplishing this work, but does not have better reinforcing bar on the market and consolidate cement panel processing equipment, so designed this kind of reinforcing bar for civil construction and consolidated cement panel processing equipment.

Disclosure of Invention

The invention mainly solves the technical problem of providing a processing device for reinforcing a cement plate by using a steel bar for a civil construction, wherein the device can transversely transmit the steel bar into a cavity of a cement plate grinding tool, the device can transversely transmit the plate and then enter and exit cement into the cement plate grinding tool, the device can longitudinally transmit the steel bar into and exit from the cement plate grinding tool and enter the cavity, the device can cut the transmitted steel bar after the cement is solidified, and the device can output the cement plate reinforced by the steel bar.

In order to solve the technical problems, the invention relates to a reinforced cement plate processing device, in particular to a reinforced cement plate processing device for civil construction, which comprises a conveying linkage mechanism and a cutting linkage mechanism, wherein the reinforced cement plate processing device can transversely convey reinforcing steel bars into a cement plate grinding tool cavity, cement can enter and exit from the cement plate grinding tool after the reinforced cement plate is transversely conveyed, cement can longitudinally convey the reinforcing steel bars into the cement plate grinding tool and enter the cement plate grinding tool after the cement is solidified, the reinforced cement plate can be cut after the reinforced cement is solidified, and the reinforced cement plate can be output by the reinforced cement plate output device.

The conveying linkage mechanism is connected with the cutting linkage mechanism.

According to the technical scheme, the knocking driving mechanism comprises a motor a, a motor shaft a, a belt a, a connecting shaft a, a conveying belt a, transverse steel bars, a steel bar sliding groove a, a connecting shaft b, a belt b, a connecting shaft c, a bevel gear a, a bevel gear b, a connecting shaft d, a reset spring, a limiting block, a belt c, a connecting shaft e, a conveying belt b, a connecting shaft f, longitudinal steel bars, a steel bar sliding groove b, an equipment installation box, a connecting plate a, a connecting plate b, a connecting plate c, a connecting plate d, a connecting plate e, a connecting plate f, a sliding limiting block, a connecting plate g, a connecting plate h, a belt d, a connecting shaft g, a propeller, a cement box, an output pipe, a sliding pipe a, a sliding pipe sealing column, a supporting spring, a connecting plate i, a connecting plate j, a connecting plate k, The cement bottom supporting plate and the connecting plate l, the motor a is connected with the motor shaft a, the motor a is connected with the equipment installation box, the motor shaft a is in friction connection with the belt a, the belt a is in friction connection with the connecting shaft a, the connecting shaft a is in friction connection with the conveyor belt a, the connecting shaft a is in bearing connection with the connecting plate b, the conveyor belt a is in friction connection with the transverse steel bar, the conveyor belt a is in friction connection with the connecting shaft b, the transverse steel bar is in slide connection with the steel bar sliding groove a, the transverse steel bar is in slide connection with the connecting plate c, the steel bar sliding groove a is connected with the connecting plate k, the connecting shaft b is in friction connection with the belt b, the connecting shaft b is in bearing connection with the connecting plate b, the belt b is in friction connection with the connecting shaft c, the connecting shaft c is in bearing connection with the connecting plate d, the connecting shaft c is in bearing connection with the connecting plate g, the bevel gear b is connected with the connecting shaft d, and the connecting shaft d is in bearing connection with the limiting block, a connecting shaft d is connected with a connecting plate h through a bearing, a reset spring is sleeved on the connecting shaft d and limited on a limiting block and the connecting plate h, the limiting block is connected with the connecting plate d in a sliding manner, the limiting block is connected with the connecting plate e in a sliding manner, one end of a belt c is connected with the connecting shaft d in a friction manner, the other end of the belt c is connected with the connecting shaft e in a friction manner, the connecting shaft e is connected with a driving belt b in a friction manner, the connecting shaft e is connected with a connecting plate f through a bearing, the driving belt b is connected with a connecting shaft f in a friction manner, the connecting shaft f is connected with a connecting plate f through a bearing, a longitudinal steel bar is connected with a steel bar sliding groove b in a sliding manner, the longitudinal steel bar is connected with the connecting plate e in a sliding manner, the steel bar sliding groove b is connected with the connecting plate k, an equipment installation box is connected with the connecting plate a, the equipment installation box is connected with the connecting plate b in a sliding manner, the equipment installation box is connected with a connecting plate d, the equipment installation box is connected with a connecting plate e in a sliding manner, the equipment installation box is connected with a connecting plate h, the equipment installation box is connected with a connecting plate f in a sliding manner, the equipment installation box is connected with a sliding limiting block, the equipment installation box is connected with a connecting plate k, the equipment installation box is connected with a connecting plate l, a connecting plate a is connected with a connecting plate b in a sliding manner, a connecting plate b is connected with a connecting plate c, a connecting plate d is connected with a connecting plate h, a connecting plate e is connected with a connecting plate f, the connecting plate f is connected with a sliding limiting block in a sliding manner, a connecting plate g is connected with a connecting plate h, the connecting plate h is connected with a connecting plate k, one end of a belt d is in a friction connection with a connecting shaft d, the other end of the belt d is in friction connection with a connecting shaft g, the connecting shaft g is connected with a screw propeller, the connecting shaft g is connected with a cement box bearing, the cement box is connected with the connecting plate k, an output pipe is connected with and communicated with the cement box, output tube and sliding tube a sliding connection, the output tube is connected with connecting plate i, the output tube is connected and communicates with connecting plate k, sliding tube a and sliding tube sealing post are connected, sliding tube a and connecting plate j sliding connection, supporting spring cover on the output tube and spacing and connecting plate i and connecting plate j, connecting plate j is connected with connecting plate k, cement bottom support board and equipment fixing box sliding connection, connecting axle d passes through the belt and drives another connecting axle d rotatory.

According to further optimization of the technical scheme, the knocking execution mechanism comprises a motor b, a motor shaft b, a belt I, a connecting shaft I, a belt I, a connecting shaft II, a belt II, a special-shaped friction block, a knocking block a, a knocking block b, a knocking spring a, a knocking reset shaft, a knocking reset spring, a knocking reset plate, a linkage friction column, a hinged plate a, a hinged limiting strip, a hinged plate b, a hinged plate limiting column, a limiting column sliding rail, a belt III, a connecting shaft III, a cam, a cutting plate a, a cutting plate b, a cutting saw a, a belt IV, a connecting shaft IV, a belt V, a connecting shaft V, a cutting plate c, a cutting saw b, a reverse friction wheel, a connecting shaft VI, an inclined plate, a belt VI, a connecting shaft VII, an output friction wheel, a reverse pushing plate a, a reverse pushing shaft, a reverse spring, The reverse pushing plate b is connected with the motor b, the motor b is connected with the connecting plate k, the motor b is in friction connection with the belt I, the belt I is in friction connection with the connecting shaft I, the connecting shaft I is connected with the linkage friction column, the connecting shaft I is connected with the connecting plate k bearing, the belt I is in friction connection with the two connecting shafts II, the connecting shafts II are connected with the special-shaped friction blocks, the connecting shafts II are in sliding connection with the knocking reset plate, the connecting shafts II are connected with the connecting plate k bearing, one end of the belt II is in friction connection with the connecting shaft I, the other end of the belt II is in friction connection with the connecting shaft II, the special-shaped friction blocks are in sliding connection with the knocking block a, the knocking block a is in sliding connection with the knocking block b, the knocking block b is connected with the knocking reset plate, one end of the knocking spring a is connected with the knocking block a, the other end of the knocking reset shaft is connected with the connecting plate k, and the other end of the knocking reset plate is in sliding connection with the knocking reset plate, the knocking reset spring is sleeved on the knocking reset shaft and limited on the knocking reset plate and a connecting plate k, the linkage friction column is in friction connection with a hinged plate a, the hinged plate a is in sliding connection with a hinged limiting strip, the hinged plate a is hinged with a hinged plate b, the hinged limiting strip connecting plate k is connected, the hinged plate b is connected with a hinged plate limiting column, the hinged plate limiting column is in sliding connection with a limiting column sliding rail, one limiting column sliding rail is connected with a connecting plate c, the other limiting column sliding rail is connected with a connecting plate e, one end of a belt is in friction connection with a connecting shaft II, the other end of the belt is in friction connection with a connecting shaft III, the connecting shaft III is connected with a cam, the connecting shaft III is in friction connection with a belt IV, the connecting shaft III is in friction connection with a connecting shaft VII, the connecting shaft III is connected with an equipment installation box bearing, the cam is in sliding connection with a cutting plate a, the cutting plate a is connected with a cutting plate b, and the cutting plate a is connected with a cutting saw a, the cutting board b is connected with the cutting saw a, the cutting saw a is connected with the equipment installation box in a sliding mode, the cutting board b is connected with the four threads of the connecting shaft, the belt four is in friction connection with the four threads of the connecting shaft, the connecting shaft four is in friction connection with the belt five, the belt five is in friction connection with the connecting shaft five, the connecting shaft five is in thread connection with the cutting board c, the cutting board c is connected with the cutting saw b, the cutting board c is connected with the reverse pushing board a, the cutting saw b is in sliding connection with the connecting plate k, the reverse friction wheel is connected with the connecting shaft six, one reverse friction wheel is in friction connection with the cutting saw a, the other reverse friction wheel is in friction connection with the cutting saw b, the upper portion of the six connecting shaft is connected with an equipment installation box bearing, the inclined plate is connected with the equipment installation box, the six connecting shaft of the belt is in friction connection with the seven connecting shaft, the seven connecting shaft is connected with an output friction wheel, the seven connecting shaft is connected with an equipment installation box bearing, the output friction wheel is in friction connection with a cement bottom supporting plate, reverse catch bar a is connected with reverse catch bar, reverse catch bar and reverse catch bar b sliding connection, and reverse spring housing is epaxial and spacing in reverse catch bar a and reverse catch bar b in reverse catch bar, and reverse catch bar b is connected with the equipment fixing box.

According to the processing equipment for the reinforcing cement plate for the civil construction, disclosed by the invention, carborundum is plated on the upper parts of the cutting saw a and the cutting saw b, so that reinforcing steel bars and cement can be cut.

The processing equipment for reinforcing the cement board by the steel bar for the civil construction has the beneficial effects that:

according to the processing equipment for reinforcing the cement board by the reinforcing steel bar for the civil construction, disclosed by the invention, the reinforcing steel bar can be transversely conveyed into the cavity of the cement board grinding tool by the equipment, cement can enter and exit from the cement board grinding tool after the board is transversely conveyed, the reinforcing steel bar can be longitudinally conveyed into the cavity after the cement enters and exits from the cement board grinding tool by the equipment, the conveyed reinforcing steel bar can be cut by the equipment after the cement is solidified, and the reinforcing steel bar can be output by the equipment.

Drawings

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

Fig. 1 is a first structural schematic diagram of the processing equipment for reinforcing a cement plate for a civil construction.

Fig. 2 is a schematic structural diagram of a second processing device for reinforcing a cement plate for a civil construction.

Fig. 3 is a first structural schematic diagram of a transmission linkage mechanism 1 of the reinforced cement plate processing equipment for civil construction.

Fig. 4 is a second structural schematic diagram of the conveying linkage mechanism 1 of the reinforced cement plate processing equipment for civil construction.

Fig. 5 is a third structural schematic diagram of the conveying linkage mechanism 1 of the reinforced cement plate processing equipment for civil construction.

Fig. 6 is a fourth schematic structural view of the conveying linkage mechanism 1 of the reinforced cement plate processing equipment for civil construction.

Fig. 7 is a fifth structural schematic view of the conveying linkage mechanism 1 of the reinforcing steel bar reinforced cement plate processing equipment for civil construction.

Fig. 8 is a sixth schematic structural view of the conveying linkage mechanism 1 of the reinforcing steel bar reinforced cement plate processing equipment for civil construction.

Fig. 9 is a seventh structural schematic view of the conveying linkage mechanism 1 of the reinforcing steel bar reinforced cement plate processing equipment for civil construction.

Fig. 10 is a first structural schematic view of a cutting linkage mechanism 2 of the reinforcing steel bar reinforced cement plate processing equipment for civil construction.

Fig. 11 is a second structural schematic diagram of the cutting linkage mechanism 2 of the reinforcement cement plate processing equipment for civil buildings.

Fig. 12 is a third structural schematic view of the cutting linkage mechanism 2 of the reinforcing steel bar reinforced cement plate processing equipment for civil construction.

Fig. 13 is a fourth schematic structural view of the cutting linkage mechanism 2 of the reinforcing steel bar reinforced cement plate processing equipment for civil construction.

In the figure: a transmission linkage mechanism 1; motor a 1-1; motor shaft a 1-2; belt a 1-3; connecting shaft a 1-4; belt a 1-5; 1-6 parts of transverse steel bars; a steel bar sliding groove a 1-7; connecting shaft b 1-8; belt b 1-9; connecting shaft c 1-10; bevel gear a 1-11; bevel gear b 1-12; connecting shaft d 1-13; a return spring 1-14; 1-15 parts of a limiting block; belts c 1-16; connecting shaft e 1-17; belt b 1-18; connecting shafts f 1-19; 1-20 parts of longitudinal steel bars; a steel bar sliding groove b 1-21; equipment installation boxes 1-22; connection board a 1-23; connecting plate b 1-24; connecting plates c 1-25; connecting plates d 1-26; connecting plate e 1-27; connection plate f 1-28; a sliding stopper 1-29; connecting plates g 1-30; connecting plates h 1-31; belts d 1-32; connecting shafts g 1-33; 1-34 of propellers; 1-35 parts of cement box; an output pipe 1-36; sliding tubes a 1-37; sliding tube sealing columns 1-38; support springs 1-39; connecting plates i 1-40; connection plate j 1-41; connecting plates k 1-42; cement bottom support plates 1-43; webs l 1-44; a cutting linkage mechanism 2; motor b 2-1; motor shaft b 2-2; 2-3 parts of a first belt; connecting shafts I2-4; 2-5 parts of a first belt; connecting shafts II 2-6; 2-7 parts of a second belt; 2-8 of special-shaped friction blocks; knock block a 2-9; knocking block b 2-10; knocking spring a 2-11; knocking the reset shaft 2-12; knocking the reset springs 2-13; knocking the reset plates 2-14; 2-15 of linkage friction column; hinge plates a 2-16; hinged limiting strips 2-17; hinge plate b 2-18; hinge plate limit posts 2-19; 2-20 parts of a limiting column slide rail; 2-21 parts of a third belt; connecting shafts III 2-22; 2-23 of a cam; cutting boards a 2-24; cutting boards b 2-25; dicing saws a 2-26; belts IV 2-27; connecting shafts IV 2-28; a belt five 2-29; connecting shafts five 2-30; cutting boards c 2-31; dicing saws b 2-32; 2-33 of a reverse friction wheel; connecting shafts six 2-34; inclined plates 2-35; six belts 2-36; connecting shafts seven 2-37; output friction wheels 2-38; the reverse pushing plate a 2-39; pushing the shaft 2-40 reversely; reverse springs 2-41; pushing the panels b2-42 in opposite directions.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, and fig. 13, and the present invention relates to a reinforced cement board processing device, and more specifically, to a reinforced cement board processing device for civil construction, which includes a transmission linkage mechanism 1 and a cutting linkage mechanism 2, and the device can transversely transmit a reinforcing steel bar into a cavity of a cement board grinding tool, and can enter and exit cement into and from the cement board grinding tool after transversely transmitting a board, and the device can longitudinally transmit a reinforcing steel bar into and exit from the cavity of the cement board grinding tool, and can cut the transmitted reinforcing steel bar after cement is solidified, and the device can output a reinforced cement board.

The conveying linkage mechanism 1 is connected with the cutting linkage mechanism 2.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, and the embodiment further describes the embodiment, where the knocking driving mechanism 1 includes a motor a1-1, a motor shaft a1-2, a belt a1-3, a connecting shaft a1-4, a conveyor belt a1-5, transverse steel bars 1-6, steel bar sliding grooves a1-7, a connecting shaft b1-8, a belt b1-9, a connecting shaft c1-10, a helical gear a1-11, a belt b1-12, a connecting shaft d1-13, a return spring 1-14, a limiting block 1-15, a belt c1-16, a helical gear e1-17, a drive belt b1-18, a connecting shaft f1-19, longitudinal steel bars 1-20, a connecting shaft d1-13, a return spring 1-14, a reset spring, a connecting shaft b 366, a helical gear b, Reinforcing steel bar sliding grooves b1-21, equipment installation boxes 1-22, connecting plates a1-23, connecting plates b1-24, connecting plates c1-25, connecting plates d1-26, connecting plates e1-27, connecting plates f1-28, sliding limit blocks 1-29, connecting plates g1-30, connecting plates h1-31, belts d1-32, connecting shafts g1-33, propellers 1-34, cement boxes 1-35, output pipes 1-36, sliding pipes a1-37, sliding pipe sealing columns 1-38, supporting springs 1-39, connecting plates i1-40, connecting plates 36j 1-41, connecting plates k1-42, cement bottom supporting plates 1-43 and connecting plates l1-44, motors a1-1 are connected with motor shafts a1-2, motors a1-1 are connected with the equipment installation boxes 1-22, the motor shaft a1-2 is in friction connection with the belt a1-3, the belt a1-3 is in friction connection with the connecting shaft a1-4, the connecting shaft a1-4 is in friction connection with the conveyor belt a1-5, the connecting shaft a1-4 is in bearing connection with the connecting plate b1-24, the conveyor belt a1-5 is in friction connection with the transverse steel bars 1-6, the conveyor belt a1-5 is in friction connection with the connecting shaft b1-8, the transverse steel bars 1-6 are in sliding connection with the steel bar sliding grooves a1-7, the transverse steel bars 1-6 are in sliding connection with the connecting plates c1-25, the steel bar sliding grooves a1-7 are in connection with the connecting plates k1-42, the connecting shaft b1-8 is in friction connection with the belt b1-9, the connecting shaft b1-8 is in bearing connection with the connecting plates b1-24, and the belt b1-9 is in friction connection with the connecting shaft c1-10, a connecting shaft c1-10 is connected with a helical gear a1-11, a connecting shaft c1-10 is connected with a connecting plate d1-26 through a bearing, a connecting shaft c1-10 is connected with a connecting plate g1-30 through a bearing, a helical gear b1-12 is connected with a connecting shaft d1-13, a connecting shaft d1-13 is connected with a limiting block 1-15 through a bearing, a connecting shaft d1-13 is connected with a connecting plate h1-31 through a bearing, a return spring 1-14 is sleeved on the connecting shaft d1-13 and limited on the limiting block 1-15 and the connecting plate h1-31, a limiting block 1-15 is connected with a connecting plate d1-26 in a sliding manner, a limiting block 1-15 is connected with a connecting plate e1-27 in a sliding manner, a limiting block 1-15 is connected with a connecting plate 1-42 in a sliding manner, one end of a belt c1-16 is connected with the connecting shaft d1-13 through a friction manner, and the other end is connected with a connecting shaft e1-17 through a friction manner, connecting shafts e1-17 are in friction connection with driving belts b1-18, connecting shafts e1-17 are in bearing connection with connecting plates f1-28, driving belts b1-18 are in friction connection with connecting shafts f1-19, driving belts b1-18 are in friction connection with longitudinal steel bars 1-20, connecting shafts f1-19 are in bearing connection with connecting plates f1-28, longitudinal steel bars 1-20 are in sliding connection with steel bar sliding grooves b1-21, longitudinal steel bars 1-20 are in sliding connection with connecting plates e1-27, steel bar sliding grooves b1-21 are in sliding connection with connecting plates k1-42, equipment installation boxes 1-22 are in sliding connection with connecting plates a1-23, equipment installation boxes 1-22 are in sliding connection with connecting plates b1-24, equipment installation boxes 1-22 are in sliding connection with connecting plates c1-25, equipment installation boxes 1-22 are in sliding connection with connecting plates d1-26, the equipment installation boxes 1-22 are connected with connecting plates e1-27 in a sliding manner, the equipment installation boxes 1-22 are connected with connecting plates h1-31, the equipment installation boxes 1-22 are connected with connecting plates f1-28 in a sliding manner, the equipment installation boxes 1-22 are connected with sliding limit blocks 1-29, the equipment installation boxes 1-22 are connected with connecting plates k1-42, the equipment installation boxes 1-22 are connected with connecting plates l1-44, connecting plates a1-23 are connected with connecting plates b1-24 in a sliding manner, connecting plates b1-24 are connected with connecting plates c1-25, connecting plates d1-26 are connected with connecting plates h1-31, connecting plates e1-27 are connected with connecting plates f1-28, connecting plates f1-28 are connected with sliding limit blocks 1-29 in a sliding manner, connecting plates g1-30 are connected with connecting plates h1-31, the connecting plate h1-31 is connected with the connecting plate k1-42, one end of a belt d1-32 is in friction connection with the connecting shaft d1-13, the other end of the belt d is in friction connection with the connecting shaft g1-33, the connecting shaft g1-33 is connected with the propeller 1-34, the connecting shaft g1-33 is in bearing connection with the cement box 1-35, the cement box 1-35 is connected with the connecting plate k1-42, the output pipe 1-36 is connected and communicated with the cement box 1-35, the output pipe 1-36 is in sliding connection with the sliding pipe a1-37, the output pipe 1-36 is connected with the connecting plate i1-40, the output pipe 1-36 is connected and communicated with the connecting plate k1-42, the sliding pipe a1-37 is connected with the sliding pipe sealing column 1-38, the sliding pipe a1-37 is in sliding connection with the connecting plate j1-41, the supporting spring 1-39 is sleeved on the output pipe 1-36, and the limiting and connecting plate i1-40 is connected with the connecting plate k 3542 The connecting plates j1-41 and the connecting plates j1-41 are connected with the connecting plates k1-42, cement bottom supporting plates 1-43 are connected with the equipment installation boxes 1-22 in a sliding mode, the connecting shafts d1-13 drive the other connecting shaft d1-13 to rotate through belts, equipment can transversely convey reinforcing steel bars into a cement plate grinding tool cavity, the equipment can convey cement into and out of the cement plate grinding tool after plates are transversely conveyed, the equipment can convey cement into and out of the cement plate grinding tool and convey the reinforcing steel bars into the cement plate grinding tool longitudinally, a motor a1-1 works, the motor a1-1 works to drive a motor shaft a1-2 to rotate, the motor shaft a1-2 rotates to drive the connecting shaft a1-4 to rotate through the belts a1-3, the connecting shaft a1-4 rotates to drive the connecting shafts b 1-468 to rotate through the conveying belts a1-5, and when the conveying belts a 7384-5 rotate, the transverse reinforcing steel bars 1-6 can be conveyed to the limiting blocks 1-15 The transverse steel bars 1-6 are conveyed under the limitation of the steel bar sliding grooves a1-7, when the transverse steel bars 1-6 are conveyed to be contacted with the limiting blocks 1-15, the transverse steel bars 1-6 are conveyed continuously, the limiting blocks 1-15 are pressed by the transverse steel bars 1-6 at the moment, the limiting blocks 1-15 can automatically reset under the action of the reset springs 1-14, the limiting blocks 1-15 are pressed to press the connecting shaft d1-13 to move towards the direction of the connecting plate h1-31, when the bevel gears b1-12 on the connecting shaft d1-13 move to be contacted with the bevel gears a1-11, the bevel gears b1-12 move to the limit positions, the connecting shaft b1-8 rotates to drive the connecting shaft c1-10 to rotate through the belt b1-9, the connecting shaft c1-10 rotates to drive the bevel gears a1-11 to rotate, when the helical gear a1-11 rotates, the helical gear a1-11 rotates to drive the helical gear b1-12 to rotate, the helical gear b1-12 rotates to drive the connecting shaft d1-13 to rotate, the connecting shaft d1-13 drives the other connecting shaft d1-13 to rotate through a belt, the connecting shaft d1-13 rotates to drive the connecting shaft e1-17 to rotate through the belt c1-16, the connecting shaft e1-17 rotates to drive the connecting shaft f1-19 to rotate through the driving belt b1-18, the longitudinal steel bars 1-20 can be transmitted to the direction of the belt b1-9 when the driving belt b1-18 moves, the connecting shaft d1-13 rotates to drive the connecting shaft g1-33 to rotate through the belts d1-32, the connecting shaft g1-33 rotates to drive the propellers 1-34 to rotate, the propellers 1-34 rotate to press liquid cement in the cement box 1-35 to the sliding pipe a1-37, the other end of the sliding tube a1-37 is blocked by the sliding tube sealing column 1-38, at this time, the pressing force acts on the sliding tube a1-37 and the sliding tube sealing column 1-38, the sliding tube a1-37 and the sliding tube sealing column 1-38 are driven to slide towards the connecting plate j1-41, the sliding tube a1-37 can automatically reset under the action of the supporting spring 1-39, when the sliding tube a1-37 slides to the hole on the sliding tube a1-37 and is superposed with the lower side tube of the output tube 1-36, the cement is discharged into the cement plate grinding tool cavity formed by the limiting block 1-15, the connecting plate c1-25, the connecting plate d1-26, the connecting plate e1-27, the connecting plate k1-42 and the cement bottom supporting plate 1-43 through the output tube 1-36.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, and further described, wherein the knocking actuator 2 includes a motor b2-1, a motor shaft b2-2, a belt i 2-3, a connecting shaft i 2-4, a belt i 2-5, a connecting shaft ii 2-6, a belt ii 2-7, a shaped friction block 2-8, a knocking block a2-9, a knocking block b2-10, a knocking spring a2-11, a knocking reset shaft 2-12, a knocking reset spring 2-13, a knocking reset plate 2-14, a linkage friction column 2-15, a hinge plate a2-16, a hinge limit strip 2-17, a hinge plate b2-18, a knocking reset spring 2-13, a hinge plate b 2-14, a linkage friction column 2-15, a hinge plate a2-16, a hinge limit strip 2-17, a hinge plate b2-18, and a, 2-19 parts of hinge plate limiting columns, 2-20 parts of limiting column sliding rails, 2-21 parts of belts, 2-22 parts of connecting shafts, 2-23 parts of cams, 2-24 parts of cutting plates a, 2-25 parts of cutting plates b, 2-26 parts of cutting saws a, 2-27 parts of belts four, 2-28 parts of connecting shafts four, 2-29 parts of belts five, 2-30 parts of connecting shafts five, 2-31 parts of cutting plates c, 2-32 parts of cutting saws b, 2-33 parts of reverse friction wheels, 2-34 parts of connecting shafts six, 2-35 parts of inclined plates, 2-36 parts of belts six, 2-37 parts of connecting shafts seven, 2-38 parts of output friction wheels, 2-39 parts of reverse pushing plates a2-39 parts of reverse pushing shafts 2-40 parts of reverse springs 2-41 parts of reverse pushing plates b2-42 parts of reverse pushing plates b2-1 parts of motors are connected with b2-2 parts of motor shafts, the motor b2-1 is connected with a connecting plate k1-42, the motor shaft b2-2 is in friction connection with a belt I2-3, the belt I2-3 is in friction connection with a connecting shaft I2-4, the connecting shaft I2-4 is connected with a linkage friction column 2-15, the connecting shaft I2-4 is in bearing connection with the connecting plate k1-42, the belt I2-5 is in friction connection with two connecting shafts II 2-6, the connecting shaft II 2-6 is connected with a special-shaped friction block 2-8, the connecting shaft II 2-6 is in sliding connection with a knocking plate 2-14, the connecting shaft II 2-6 is in bearing connection with the connecting plate k1-42, one end of the belt II 2-7 is in friction connection with the connecting shaft I2-4, the other end is in friction connection with the connecting shaft II 2-6, the special-shaped friction block 2-8 is in sliding connection with the knocking block a2-9, the knocking block a2-9 is connected with the knocking block b2-10 in a sliding mode, the knocking block b2-10 is connected with a knocking reset plate 2-14, one end of a knocking spring a2-11 is connected with the knocking block a2-9, the other end of the knocking spring a2-9 is connected with the knocking block b2-10, one end of a knocking reset shaft 2-12 is connected with a connecting plate k1-42, the other end of the knocking reset shaft is connected with a knocking reset plate 2-14 in a sliding mode, the knocking reset spring 2-13 is sleeved on the knocking reset shaft 2-12 and limited on the knocking reset plate 2-14 and the connecting plate k1-42, the linkage friction column 2-15 is in friction connection with the hinge plate a2-16, the hinge plate a2-16 is in sliding connection with a hinge limiting strip 2-17, the hinge plate a2-16 is hinged with the hinge plate b2-18, the hinge limiting strip 2-17 is connected with the connecting plate k1-42, the hinged plate b2-18 is connected with hinged plate limiting columns 2-19, the hinged plate limiting columns 2-19 are connected with limiting column slide rails 2-20 in a sliding manner, one limiting column slide rail 2-20 is connected with a connecting plate c1-25, the other limiting column slide rail 2-20 is connected with a connecting plate e1-27, one end of a belt III 2-21 is in friction connection with a connecting shaft II 2-6, the other end of the belt III is in friction connection with a connecting shaft III 2-22, the connecting shaft III 2-22 is connected with a cam 2-23, the connecting shaft III 2-22 is in friction connection with a belt IV 2-27, the connecting shaft III 2-22 is in friction connection with a connecting shaft VII 2-37, the connecting shaft III 2-22 is in bearing connection with an equipment installation box 1-22, the cam 2-23 is in sliding connection with a cutting plate a2-24, the cutting plate a2-24 is connected with a cutting plate b 2-25, the cutting board a2-24 is connected with a cutting saw a2-26, the cutting board b 2-25 is connected with a cutting saw a2-26, the cutting saw a2-26 is connected with an equipment installation box 1-22 in a sliding mode, the cutting board b 2-25 is connected with a connecting shaft four 2-28 in a threaded mode, a belt four 2-27 is connected with a connecting shaft four 2-28 in a friction mode, the connecting shaft four 2-28 is connected with a belt five 2-29 in a friction mode, the belt five 2-29 is connected with a connecting shaft five 2-30 in a friction mode, the connecting shaft five 2-30 is connected with a cutting board c2-31 in a threaded mode, the cutting board c2-31 is connected with a cutting saw b2-32, the cutting board c2-31 is connected with a reverse pushing board a2-39, the cutting saw b2-32 is connected with a connecting plate k1-42 in a sliding mode, a reverse friction wheel 2-33 is connected with a connecting shaft six 2-34, one reverse friction wheel 2-33 is in friction connection with a cutting saw a2-26, the other reverse friction wheel 2-33 is in friction connection with a cutting saw b2-32, the upper part of a connecting shaft six 2-34 is in bearing connection with an equipment installation box 1-22, an inclined plate 2-35 is in friction connection with the equipment installation box 1-22, a belt six 2-36 is in friction connection with a connecting shaft seven 2-37, a connecting shaft seven 2-37 is in friction connection with an output friction wheel 2-38, a connecting shaft seven 2-37 is in bearing connection with an equipment installation box 1-22, an output friction wheel 2-38 is in friction connection with a cement bottom support plate 1-43, a reverse push plate a2-39 is connected with a reverse push shaft 2-40, a reverse push shaft 2-40 is in sliding connection with a reverse push plate b2-42, a reverse spring 2-41 is sleeved on the reverse push shaft 2-40 and limited by the reverse push plate a2-39 and the reverse push plate b The device comprises a pushing plate b2-42 and a reverse pushing plate b2-42 which are connected with a device installation box 1-22, the device can cut steel bars conveyed into the device after cement is solidified, the device can output the cement plate reinforced by the steel bars, a motor b2-1 works, the motor b2-1 works to drive a motor shaft b2-2 to rotate, the motor shaft b2-2 rotates to drive a connecting shaft I2-4 to rotate through a belt I2-3, the connecting shaft I2-4 rotates to drive a linkage friction column 2-15 to rotate, the linkage friction column 2-15 rotates to drive a hinge plate a2-16 to slide first under the limitation of a hinge limiting strip 2-17, the hinge plate a2-16 moves to drive a hinge plate b2-18 to move, the hinge plate b2-18 moves to drive a hinge plate limiting column 2-19 to move, and the hinge plate limiting column 2-19 can push a connecting plate c1 under the action of a limiting column sliding rail 2-20 25 and the connecting plate e1-27 slide towards the direction far away from the center of the equipment, at the moment, the connecting plate c1-25 is separated from the connecting plate e1-27 to generate a gap, the belt II 2-7 is driven to drive the connecting shaft II 2-6 to rotate when the connecting shaft I2-4 rotates, the connecting shaft II 2-6 rotates to drive the other connecting shaft II 2-6 to rotate through the belt I2-5, the connecting shaft II 2-6 rotates to drive the special-shaped friction block 2-8 to rotate, the special-shaped friction block 2-8 rotates to press the knocking block a2-9, the knocking block a2-9 can knock the connecting plate k1-42 downwards under the action of the knocking block b2-10 and the knocking spring a2-11 to generate a gap between the connecting plate k1-42 and the solidified cement, and under the action of the knocking spring a2-11, the knocking block b2-10 can not generate excessive force to damage equipment when performing knocking work, the knocking block b2-10 can automatically reset under the action of a knocking reset spring 2-13, namely the knocking block b2-10 can reciprocate up and down, the connecting plate k1-42 is knocked when moving downwards, the connecting shaft II 2-6 drives the connecting shaft III 2-22 to rotate through the belt III 2-21 when rotating, the connecting shaft III 2-22 rotates to drive the cam 2-23 to rotate, the cam 2-23 rotates to drive the cutting plate a2-24 to longitudinally slide, the cutting plate a2-24 pushes the cutting plate b 2-25 and the cutting saw a2-26 to longitudinally move in a small amplitude manner when sliding, the connecting shaft III 2-22 also drives the connecting shaft IV 2-28 to rotate through the belt IV 2-27 when rotating, the connecting shaft IV 2-28 rotates to drive the cutting saw a2-26 to upwards through the cutting plate b 2-25, namely the cutting saw a2-26 moves longitudinally and moves upwards, when the cutting saw a2-26 moves, the cutting saw b2-32 is driven to move transversely by the reverse friction wheel 2-33 and the connecting shaft six 2-34, the cutting saw a2-26 and the cutting saw b2-32 can reset automatically under the action of the reverse spring 2-41, namely the cutting saw a2-26 and the cutting saw b2-32 move upwards and reciprocate transversely or longitudinally, the process can cut the steel bars conveyed in after cement is solidified, when the connecting shaft three 2-22 rotates, the connecting shaft seven 2-36 drives the connecting shaft seven 2-37 to rotate, the connecting shaft seven 2-37 drives the other connecting shaft seven 2-37 to rotate by the other connecting shaft six 2-36, the seven 2-37 rotate and drive the two output friction wheels 2-38 to rotate, the output friction wheels 2-38 rotate to drive the cement bottom supporting plates 1-43 to slide towards the connecting plates l1-44, the lower parts of cement plate grinding tool cavities formed by the limiting blocks 1-15, the connecting plates c1-25, the connecting plates d1-26, the connecting plates e1-27, the connecting plates k1-42 and the cement bottom supporting plates 1-43 can be opened in the process, the cement plates reinforced by reinforcing steel bars can be output to the inclined plates 2-35 under the knocking function of matching equipment, and the equipment is output under the action of the inclined plates 2-35.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, and fig. 13, and the present embodiment further describes an embodiment in which the cutting saws a2-26 and b2-32 are coated with carborundum to cut steel bars and cement.

The working principle of the device is as follows: the device can transversely convey reinforcing steel bars into a cement board grinding tool cavity, the device can transversely convey plates and then convey cement into and out of the cement board grinding tool, the device can longitudinally convey the reinforcing steel bars into and out of the cement board grinding tool and then into the cavity, a motor a1-1 works, a motor a1-1 works to drive a motor shaft a1-2 to rotate, a motor shaft a1-2 rotates to drive a connecting shaft a1-4 to rotate through a belt a1-3, the connecting shaft a1-4 rotates to drive a connecting shaft b1-8 to rotate through a conveyor belt a1-5, when the conveyor belt a1-5 rotates, the transverse reinforcing steel bars 1-6 can be conveyed to the direction of the limiting blocks 1-15, the transverse reinforcing steel bars 1-6 are conveyed under the limitation of a1-7, and when the transverse reinforcing steel bars 1-6 are conveyed to be contacted with the limiting blocks 1-15, the transverse steel bars 1-6 are continuously conveyed, the transverse steel bars 1-6 are pressed against the limiting blocks 1-15 at the moment, the limiting blocks 1-15 can automatically reset under the action of the reset springs 1-14, the limiting blocks 1-15 are pressed against the connecting shaft d1-13 to move towards the direction of the connecting plate h1-31, the bevel gear b1-12 on the connecting shaft d1-13 moves to be contacted with the bevel gear a1-11, the bevel gear b1-12 moves to the limit position, the connecting shaft b1-8 rotates to drive the connecting shaft c1-10 to rotate through the belt b1-9, the connecting shaft c1-10 rotates to drive the bevel gear a1-11 to rotate, when the bevel gear a1-11 rotates, the bevel gear a1-11 rotates to drive the bevel gear b1-12 to rotate, the bevel gear b1-12 rotates to drive the bevel gear d1-13 to rotate, the connecting shaft d1-13 drives another connecting shaft d1-13 to rotate through a belt, the connecting shaft d1-13 rotates and drives the connecting shaft e1-17 to rotate through a belt c1-16, the connecting shaft e1-17 rotates and drives the connecting shaft f1-19 to rotate through a transmission belt b1-18, when the transmission belt b1-18 moves, the longitudinal steel bars 1-20 can be transmitted to the direction of the belt b1-9, when the connecting shaft d1-13 rotates, the connecting shaft g1-33 is also driven to rotate through the belt d1-32, the connecting shaft g1-33 rotates and drives the propellers 1-34 to rotate, the propellers 1-34 rotate and can press the liquid cement in the cement boxes 1-35 to the sliding tubes a1-37, the other ends of the sliding tubes a1-37 are blocked by the sliding tube sealing columns 1-38, and at the time, the sealing force is applied to the sliding tubes a1-37 and the sliding tubes 1-38, the sliding tubes a1-37 and the sliding tube sealing columns 1-38 are driven to slide towards the connecting plates j1-41, the sliding tubes a1-37 can automatically reset under the action of the supporting springs 1-39, when the sliding tubes a1-37 slide to the holes in the sliding tubes a1-37 and the lower side tubes of the output tubes 1-36 are overlapped, cement is discharged into a cement plate grinding tool cavity formed by the limiting blocks 1-15, the connecting plates c1-25, the connecting plates d1-26, the connecting plates e1-27, the connecting plates k1-42 and the cement bottom supporting plates 1-43 through the output tubes 1-36, the device can cut steel bars conveyed into the cement after the cement is solidified, the device can output the cement plate reinforced by the steel bars, the motor b2-1 works, the motor b2-1 works to drive the motor shaft b2-2 to rotate, the motor shaft b2-2 rotates to drive the connecting shaft I2-4 to rotate through the belt I2-3, the connecting shaft I2-4 rotates to drive the linkage friction column 2-15 to rotate, the linkage friction column 2-15 rotates to drive the hinged plate a2-16 to slide firstly under the limitation of the hinged limiting strips 2-17, the hinged plate a2-16 moves to drive the hinged plate b2-18 to move, the hinged plate b2-18 moves to drive the hinged plate limiting columns 2-19 to move, the hinged plate limiting columns 2-19 can drive the connecting plate c1-25 and the connecting plate e1-27 to slide in the direction far away from the center of the equipment under the action of the limiting column sliding rails 2-20, at the moment, the connecting plate c1-25 is separated from the connecting plate e1-27 to generate a gap, the connecting shaft I2-4 rotates to drive the belt II 2-7 to drive the belt II 2-6 to rotate, the connecting shaft II 2-6 rotates to drive the other connecting shaft II 2-6 to rotate through the belt I2-5, the connecting shaft II 2-6 rotates to drive the special-shaped friction block 2-8 to rotate, the special-shaped friction block 2-8 presses the knocking block a2-9 when rotating, the knocking block a2-9 can knock the connecting plate k1-42 downwards under the action of the knocking block b2-10 and the knocking spring a2-11 to enable the connecting plate k1-42 to generate a gap with solidified cement, the knocking block b2-10 cannot generate excessive force to damage equipment when performing knocking work under the action of the knocking spring a2-11, the knocking block b2-10 can automatically reset under the action of the knocking reset spring 2-13, namely the knocking block b2-10 can reciprocate up and down, the connecting plate k1-42 is knocked when moving downwards, the connecting shaft II 2-6 drives the connecting shaft III 2-22 to rotate through the belt III 2-21 when rotating, the connecting shaft III 2-22 rotates to drive the cam 2-23 to rotate, the cam 2-23 rotates to drive the cutting board a2-24 to longitudinally slide, the cutting board a2-24 pushes the cutting board b 2-25 and the cutting saw a2-26 to longitudinally move in small amplitude when sliding, the connecting shaft III 2-22 also drives the connecting shaft IV 2-28 to rotate through the belt IV 2-27 when rotating, the connecting shaft IV 2-28 rotates to drive the cutting saw a2-26 to upwards move through the cutting board b 2-25, namely the cutting saw a2-26 generates longitudinal movement and upwards movement, and the cutting saw a2-26 also drives the cutting saw b2-32 to transversely move through the reverse friction wheels 2-33 and the connecting shaft VI 2-34 when moving, the cutting saws a2-26 and b2-32 can automatically reset under the action of the reverse springs 2-41, namely the cutting saws a2-26 and b2-32 move upwards and reciprocate transversely or longitudinally, the process can cut the steel bars conveyed in after cement is solidified, when the connecting shaft three 2-22 rotates, one connecting shaft seven 2-37 is driven to rotate by one belt six 2-36, the connecting shaft seven 2-37 drives the other connecting shaft seven 2-37 to rotate by the other belt six 2-36, the connecting shaft seven 2-37 rotates to drive the two output friction wheels 2-38 to rotate, the output friction wheels 2-38 rotate to drive the cement bottom supporting plate 1-43 to slide towards the direction of the connecting plate l1-44, and the process can enable the limiting blocks 1-15, the connecting plates c1-25, the connecting plates c 2-32 to slide towards the direction of the connecting plates l1-44, and the limiting blocks 1-15 and the connecting plates c1-25, The lower part of a cement board grinding tool cavity formed by the connecting plates d1-26, the connecting plates e1-27, the connecting plates k1-42 and the cement bottom supporting plates 1-43 is opened, so that the cement board reinforced by the reinforcing steel bars can be output to the inclined plates 2-35 under the knocking function of the matching equipment, and the equipment is output under the action of the inclined plates 2-35.

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 (4)

1. The utility model provides a cement panel processing equipment is consolidated to reinforcing bar for civil construction, includes conveying link gear (1), cutting link gear (2), its characterized in that: the conveying linkage mechanism (1) is connected with the cutting linkage mechanism (2).

2. The processing equipment of the reinforcing cement plate for the civil construction according to claim 1, wherein: the knocking driving mechanism (1) comprises a motor a (1-1), a motor shaft a (1-2), a belt a (1-3), a connecting shaft a (1-4), a conveying belt a (1-5), transverse steel bars (1-6), steel bar sliding grooves a (1-7), a connecting shaft b (1-8), a belt b (1-9), a connecting shaft c (1-10), helical gears a (1-11), helical gears b (1-12), a connecting shaft d (1-13), reset springs (1-14), limiting blocks (1-15), a belt c (1-16), a connecting shaft e (1-17), a conveying belt b (1-18), a connecting shaft f (1-19), longitudinal steel bars (1-20), steel bar sliding grooves b (1-21), The device comprises a device installation box (1-22), connecting plates a (1-23), connecting plates b (1-24), connecting plates c (1-25), connecting plates d (1-26), connecting plates e (1-27), connecting plates f (1-28), sliding limiting blocks (1-29), connecting plates g (1-30), connecting plates h (1-31), belts d (1-32), connecting shafts g (1-33), propellers (1-34), cement boxes (1-35), output pipes (1-36), sliding pipes a (1-37), sliding pipe sealing columns (1-38), supporting springs (1-39), connecting plates i (1-40), connecting plates j (1-41), connecting plates k (1-42), cement bottom supporting plates (1-43), The device comprises a connecting plate l (1-44), a motor a (1-1) is connected with a motor shaft a (1-2), the motor a (1-1) is connected with an equipment installation box (1-22), the motor shaft a (1-2) is in friction connection with a belt a (1-3), the belt a (1-3) is in friction connection with a connecting shaft a (1-4), the connecting shaft a (1-4) is in friction connection with a conveying belt a (1-5), the connecting shaft a (1-4) is in bearing connection with a connecting plate b (1-24), the conveying belt a (1-5) is in friction connection with transverse steel bars (1-6), the conveying belt a (1-5) is in friction connection with a connecting shaft b (1-8), the transverse steel bars (1-6) are in sliding connection with steel bar sliding grooves a (1-7), transverse steel bars (1-6) are connected with connecting plates c (1-25) in a sliding manner, steel bar sliding grooves a (1-7) are connected with connecting plates k (1-42), connecting shafts b (1-8) are connected with belts b (1-9) in a friction manner, connecting shafts b (1-8) are connected with connecting plates b (1-24) in a bearing manner, belts b (1-9) are connected with connecting shafts c (1-10) in a friction manner, connecting shafts c (1-10) are connected with bevel gears a (1-11), connecting shafts c (1-10) are connected with connecting plates d (1-26) in a bearing manner, connecting shafts c (1-10) are connected with connecting plates g (1-30) in a bearing manner, bevel gears b (1-12) are connected with connecting shafts d (1-13), connecting shafts d (1-13) are connected with limiting blocks (1-15) in a bearing manner, a connecting shaft d (1-13) is in bearing connection with a connecting plate h (1-31), a reset spring (1-14) is sleeved on the connecting shaft d (1-13) and limited by a limiting block (1-15) and the connecting plate h (1-31), the limiting block (1-15) is in sliding connection with the connecting plate d (1-26), the limiting block (1-15) is in sliding connection with a connecting plate e (1-27), the limiting block (1-15) is in sliding connection with a connecting plate k (1-42), one end of a belt c (1-16) is in friction connection with the connecting shaft d (1-13) and the other end is in friction connection with a connecting shaft e (1-17), the connecting shaft e (1-17) is in friction connection with a driving belt b (1-18), and the connecting shaft e (1-17) is in bearing connection with a connecting plate f (1-28), the transmission belt b (1-18) is in friction connection with a connecting shaft f (1-19), the transmission belt b (1-18) is in friction connection with a longitudinal steel bar (1-20), the connecting shaft f (1-19) is in bearing connection with a connecting plate f (1-28), the longitudinal steel bar (1-20) is in sliding connection with a steel bar sliding groove b (1-21), the longitudinal steel bar (1-20) is in sliding connection with a connecting plate e (1-27), the steel bar sliding groove b (1-21) is connected with a connecting plate k (1-42), an equipment installation box (1-22) is connected with a connecting plate a (1-23), the equipment installation box (1-22) is in sliding connection with a connecting plate b (1-24), the equipment installation box (1-22) is in sliding connection with a connecting plate c (1-25), the equipment installation box (1-22) is connected with a connecting plate d (1-26), the equipment installation box (1-22) is connected with the connecting plate e (1-27) in a sliding manner, the equipment installation box (1-22) is connected with the connecting plate h (1-31), the equipment installation box (1-22) is connected with the connecting plate f (1-28) in a sliding manner, the equipment installation box (1-22) is connected with the sliding limiting block (1-29), the equipment installation box (1-22) is connected with the connecting plate k (1-42), the equipment installation box (1-22) is connected with the connecting plate l (1-44), the connecting plate a (1-23) is connected with the connecting plate b (1-24) in a sliding manner, the connecting plate b (1-24) is connected with the connecting plate c (1-25), the connecting plate d (1-26) is connected with the connecting plate h (1-31), the connecting plate e (1-27) is connected with the connecting plate f (1-28), the connecting plate f (1-28) is connected with the sliding limiting block (1-29) in a sliding manner, the connecting plate g (1-30) is connected with the connecting plate h (1-31), the connecting plate h (1-31) is connected with the connecting plate k (1-42), one end of the belt d (1-32) is in friction connection with the connecting shaft d (1-13), the other end of the belt d (1-32) is in friction connection with the connecting shaft g (1-33), the connecting shaft g (1-33) is connected with the propeller (1-34), the connecting shaft g (1-33) is in bearing connection with the cement box (1-35), the cement box (1-35) is connected with the connecting plate k (1-42), the output pipe (1-36) is connected and communicated with the cement box (1-35), the output pipe (1-36) is in sliding connection with the sliding pipe a (1-37), the output tubes (1-36) are connected with the connecting plates i (1-40), the output tubes (1-36) are connected and communicated with the connecting plates k (1-42), the sliding tubes a (1-37) are connected with the sliding tube sealing columns (1-38), the sliding tubes a (1-37) are connected with the connecting plates j (1-41) in a sliding mode, the supporting springs (1-39) are sleeved on the output tubes (1-36) and are limited, the connecting plates i (1-40) and the connecting plates j (1-41) are connected, the connecting plates j (1-41) are connected with the connecting plates k (1-42), and the cement bottom supporting plates (1-43) are connected with the equipment installation boxes (1-22) in a sliding mode.

3. The processing equipment of the reinforcing cement plate for the civil construction according to claim 1, wherein: the knocking execution mechanism (2) comprises a motor b (2-1), a motor shaft b (2-2), a belt I (2-3), a connecting shaft I (2-4), a belt I (2-5), a connecting shaft II (2-6), a belt II (2-7), a special-shaped friction block (2-8), a knocking block a (2-9), a knocking block b (2-10), a knocking spring a (2-11), a knocking reset shaft (2-12), a knocking reset spring (2-13), a knocking reset plate (2-14), a linkage friction column (2-15), a hinge plate a (2-16), a hinge limiting strip (2-17), a hinge plate b (2-18), a hinge plate limiting column (2-19), a limiting column sliding rail (2-20), A third belt (2-21), a third connecting shaft (2-22), a cam (2-23), a cutting plate a (2-24), a cutting plate b (2-25), a cutting saw a (2-26), a fourth belt (2-27), a fourth connecting shaft (2-28), a fifth belt (2-29), a fifth connecting shaft (2-30), a cutting plate c (2-31), a cutting saw b (2-32), a reverse friction wheel (2-33), a sixth connecting shaft (2-34), an inclined plate (2-35), a sixth belt (2-36), a seventh connecting shaft (2-37), an output friction wheel (2-38), a reverse pushing plate a (2-39), a reverse pushing shaft (2-40), a reverse spring (2-41) and a reverse pushing plate b (2-42), the motor b (2-1) is connected with the motor shaft b (2-2), the motor b (2-1) is connected with the connecting plate k (1-42), the motor shaft b (2-2) is in friction connection with the belt I (2-3), the belt I (2-3) is in friction connection with the connecting shaft I (2-4), the connecting shaft I (2-4) is connected with the linkage friction column (2-15), the connecting shaft I (2-4) is in bearing connection with the connecting plate k (1-42), the belt I (2-5) is in friction connection with the two connecting shafts II (2-6), the connecting shaft II (2-6) is connected with the special-shaped friction block (2-8), the connecting shaft II (2-6) is in sliding connection with the knocking reset plate (2-14), the connecting shaft II (2-6) is in bearing connection with the connecting plate k (1-42), one end of a belt II (2-7) is in friction connection with the connecting shaft I (2-4), the other end of the belt II is in friction connection with the connecting shaft II (2-6), the special-shaped friction block (2-8) is in sliding connection with the knocking block a (2-9), the knocking block a (2-9) is in sliding connection with the knocking block b (2-10), the knocking block b (2-10) is connected with the knocking reset plate (2-14), one end of the knocking spring a (2-11) is connected with the knocking block a (2-9), the other end of the knocking spring a is connected with the knocking block b (2-10), one end of the knocking reset shaft (2-12) is connected with the connecting plate k (1-42), the other end of the knocking reset shaft is in sliding connection with the knocking reset plate (2-14), the knocking reset spring (2-13) is sleeved on the knocking reset shaft (2-12) and limited by the knocking reset plate (2-14) and the connecting plate k (1-42), the linkage friction columns (2-15) are in friction connection with hinged plates a (2-16), the hinged plates a (2-16) are in sliding connection with hinged limiting strips (2-17), the hinged plates a (2-16) are hinged with hinged plates b (2-18), the hinged limiting strips (2-17) are connected with connecting plates k (1-42), the hinged plates b (2-18) are connected with hinged plate limiting columns (2-19), the hinged plate limiting columns (2-19) are in sliding connection with limiting column sliding rails (2-20), one limiting column sliding rail (2-20) is connected with a connecting plate c (1-25), the other limiting column sliding rail (2-20) is connected with a connecting plate e (1-27), one end of a belt III (2-21) is in friction connection with a connecting shaft II (2-6), the other end of the connecting shaft III (2-22) is in friction connection with a connecting shaft III (2-22), the connecting shaft III (2-22) is connected with a cam (2-23), the connecting shaft III (2-22) is in friction connection with a belt IV (2-27), the connecting shaft III (2-22) is in friction connection with a connecting shaft VII (2-37), the connecting shaft III (2-22) is in bearing connection with an equipment installation box (1-22), the cam (2-23) is in sliding connection with a cutting plate a (2-24), the cutting plate a (2-24) is connected with a cutting plate b (2-25), the cutting plate a (2-24) is connected with a cutting saw a (2-26), the cutting plate b (2-25) is connected with the cutting saw a (2-26), and the cutting saw a (2-26) is in sliding connection with the equipment installation box (1-22), the cutting board b (2-25) is in threaded connection with the connecting shaft four (2-28), the belt four (2-27) is in frictional connection with the connecting shaft four (2-28), the connecting shaft four (2-28) is in frictional connection with the belt five (2-29), the belt five (2-29) is in frictional connection with the connecting shaft five (2-30), the connecting shaft five (2-30) is in threaded connection with the cutting board c (2-31), the cutting board c (2-31) is connected with the cutting saw b (2-32), the cutting board c (2-31) is connected with the reverse pushing board a (2-39), the cutting saw b (2-32) is in sliding connection with the connecting board k (1-42), the reverse friction wheel (2-33) is connected with the connecting shaft six (2-34), one reverse friction wheel (2-33) is in frictional connection with the cutting saw a (2-26), the other reverse friction wheel (2-33) is in friction connection with a cutting saw b (2-32), the upper part of a connecting shaft six (2-34) is in bearing connection with an equipment installation box (1-22), an inclined plate (2-35) is connected with the equipment installation box (1-22), a belt six (2-36) is in friction connection with a connecting shaft seven (2-37), the connecting shaft seven (2-37) is connected with an output friction wheel (2-38), the connecting shaft seven (2-37) is in bearing connection with the equipment installation box (1-22), the output friction wheel (2-38) is in friction connection with a cement bottom support plate (1-43), a reverse pushing plate a (2-39) is connected with a reverse pushing shaft (2-40), and the reverse pushing shaft (2-40) is in sliding connection with a reverse pushing plate b (2-42), the reverse springs (2-41) are sleeved on the reverse pushing shafts (2-40) and limited on the reverse pushing plates a (2-39) and the reverse pushing plates b (2-42), and the reverse pushing plates b (2-42) are connected with the equipment installation boxes (1-22).

4. The processing equipment of the reinforcing cement plate for the civil construction according to claim 1, wherein: the upper parts of the cutting saws a (2-26) and b (2-32) are plated with carborundum, so that steel bars and cement can be cut.

Images