CN112252131A - Road concrete laying device - Google Patents

Abstract

The invention relates to a paving device, in particular to a road concrete paving device which comprises a machine body mechanism, a stirring mechanism and a frame mechanism, wherein the machine body mechanism can feed materials dustless, can stir in multiple dimensions, can be switched to a discharging mode, is connected with the stirring mechanism and is connected with the frame mechanism.

Description

Road concrete laying device

Technical Field

The invention relates to a paving device, in particular to a road concrete paving device.

Background

In the process of laying concrete, the cement which is well mixed needs to be poured for the second time, and although the pump truck can directly pour the cement, the problem of re-mixing on site cannot be solved, so the road concrete laying device is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing a road concrete laying device, which can feed materials dustless, stir in multiple dimensions and switch to a discharging mode.

In order to solve the technical problems, the invention relates to a paving device, in particular to a road concrete paving device which comprises a machine body mechanism, a stirring mechanism and a frame mechanism, wherein the device can feed materials dustless, can stir in multiple dimensions, and can be switched to a discharging mode.

The machine body mechanism is connected with the stirring mechanism and the frame mechanism.

As a further optimization of the technical scheme, the machine body mechanism of the road concrete laying device comprises a hydraulic cylinder, a piston rod, a unthreaded hole, a base, a slide rod, a spring, a floating stirring box, a limiting block with a hole, a seat with a hole, a piston rod I, a supporting shell, a cross groove, a spring, a limiting rod, a feeding buffer box, a water inlet one-way valve, a feeding port, a feeding sliding box, a seat A with a stepped groove, a switching hydraulic cylinder, a servo motor, a coupler, a lead screw, a slide rail, a stepped slide block I, an articulated arm, an intermediate connecting seat, a door-shaped support with a hole, a limiting spring, a connecting plate I, a switching rod, a built-in slide rod, a built-in spring, a piston rod II, a gate groove, a sliding discharging pipe, a matching port, a two-way hydraulic cylinder, a rod A, a spring B and an inner groove, wherein the, the spring is sleeved on the sliding rod, the spring is abutted on the base and the floating stirring box, the floating stirring box is connected with the sliding rod in a sliding way, the sliding rod is connected with the perforated limiting block, the floating stirring box is connected with the perforated base, the perforated limiting block is connected with the piston rod I in a sliding way, the piston rod I is connected with the perforated base, the two-way hydraulic cylinder is connected with the support shell, the support shell is connected with the floating stirring box, the cross grooves are symmetrically arranged on the floating stirring box, the spring is sleeved on the limiting rod, the limiting rod is connected with the floating stirring box, the floating stirring box is connected and communicated with the feeding buffer box, the water inlet check valve is connected with the feeding buffer box, the feeding buffer box is provided with a feeding port, the feeding port is connected with the feeding sliding box, the feeding sliding box is connected with the rod A in a sliding way, the spring B is sleeved on the rod A, the spring B is abutted on, the inner groove is connected with a feeding sliding box in a sliding way, a groove seat A with steps is connected with a floating stirring box, the groove seat A with steps is connected with a switching hydraulic cylinder, a servo motor is connected with the floating stirring box, the servo motor is connected with a lead screw through the lead screw, the lead screw is connected with a slide rail through a bearing, the slide rail is connected with the floating stirring box, the lead screw is in threaded connection with a step slide block I, the step slide block I is connected with the slide rail in a sliding way, the step slide block I is hinged with a hinged arm, the hinged arm is hinged with an intermediate connecting seat, the intermediate connecting seat is connected with a door-shaped support in a sliding way, the door-shaped support with holes is connected with the floating stirring box, a limiting spring is sleeved on the intermediate connecting seat, the intermediate connecting seat is connected with a connecting plate I, the connecting plate I is connected with a connecting plate I, a switching, switching pneumatic cylinder links to each other with piston rod II, and piston rod II links to each other with the gate, gate and gate groove sliding connection, and the gate groove sets up on the sliding discharging pipe, and the sliding discharging pipe links to each other and is linked together with the agitator tank that floats, sliding discharging pipe and cooperation mouth sliding connection, and the cooperation mouth sets up on the base.

As a further optimization of the technical scheme, the stirring mechanism of the road concrete laying device comprises a special-shaped bearing seat, a motor, a belt, a motor belt pulley, a belt shaft transmission belt pulley, a belt pulley A, a belt A, a special-shaped sliding seat, a belt groove pulley, an L-shaped seat, a belt seat I, a belt slider, a chute A, an impeller shaft, a vibration spring, a vibration limiting rod, a bidirectional hydraulic cylinder A, a piston rod III, a limiting rod I, a vertical sliding hole and a transverse limiting hole, wherein the special-shaped bearing seat is in sliding connection with the belt step chute seat A, the special-shaped bearing seat is in sliding connection with an internal sliding rod, the internal spring is propped against the special-shaped bearing seat, the special-shaped bearing seat is connected with the motor, the motor is connected with the motor belt pulley, the motor belt pulley is in friction connection with the belt shaft transmission belt pulley, the belt shaft transmission, the belt pulley A is connected with the belt pulley A in a friction way, the belt A is connected with the belt pulley with a groove in a friction way, the L-shaped seat is connected with the piston rod III, the piston rod III is connected with the bidirectional hydraulic cylinder A, the bidirectional hydraulic cylinder A is connected with the special-shaped sliding seat, the special-shaped sliding seat is connected with the impeller shaft in a bearing way, the special-shaped sliding seat is connected with the cross groove in a sliding way, the special-shaped sliding seat is provided with a vertical sliding hole and a transverse limiting hole, the vertical sliding hole is connected with a limiting rod in a sliding way, the transverse limiting hole is connected with the switching rod in a sliding way, the L-shaped seat is connected with a limiting rod I, the limiting rod I is connected with a hole seat I in a sliding way, the hole seat I is connected with the belt pulley with a groove in a sliding way, the hole sliding block is connected with the sliding way A, the impeller is connected, the vibration limiting rod is connected with the sliding block with the hole in a sliding mode, and the limiting rod I is connected with the sliding block with the hole in a sliding mode.

As a further optimization of the technical scheme, the frame mechanism of the road concrete paving device comprises a moving wheel, a frame body, a moving support rod, a support shell I, a scraper with a gear, a sliding rack, a screw I, a bearing seat A, a servo motor A and a limiting groove I, wherein the moving wheel is connected with the frame body through a bearing, the frame body is connected with the moving support rod, the moving support rod is connected with a unthreaded hole in a sliding manner, the frame body is provided with the support shell I, the support shell I is connected with a hydraulic cylinder in a sliding manner, a piston rod is connected with the frame body in a sliding manner, the scraper with the gear is hinged with the frame body, the scraper with the gear is meshed with the sliding rack, the sliding rack is connected with the limiting groove I in a sliding manner, the limiting groove I is arranged on the frame body, the sliding rack is connected with the screw I in a threaded manner, and the, the bearing seat A is connected with the frame body, the screw I is connected with the servo motor A, and the servo motor A is connected with the frame body.

As a further optimization of the technical scheme, the impeller of the road concrete paving device is made of high manganese steel.

The road concrete laying device has the beneficial effects that:

according to the road concrete paving device, the device can feed materials dustless, the device can stir in multiple dimensions, and the device can be switched to a discharging mode.

Drawings

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

Fig. 1 is a schematic structural diagram of a road concrete laying device of the present invention.

Fig. 2 is a schematic structural diagram of a road concrete laying device of the present invention.

Fig. 3 is a schematic structural view three of the road concrete paving device of the present invention.

Fig. 4 is a first structural schematic diagram of the body mechanism 1 of the road concrete laying device of the present invention.

Fig. 5 is a second structural schematic diagram of the body mechanism 1 of the road concrete paving device of the present invention.

Fig. 6 is a third schematic structural diagram of the body mechanism 1 of the road concrete laying device of the present invention.

Fig. 7 is a fourth schematic structural diagram of the body mechanism 1 of the road concrete laying device of the present invention.

Fig. 8 is a fifth structural schematic diagram of the body mechanism 1 of the road concrete laying device of the present invention.

Fig. 9 is a sixth schematic structural view of the body mechanism 1 of the road concrete laying apparatus of the present invention.

Fig. 10 is a first structural schematic diagram of the stirring mechanism 2 of the road concrete paving device of the present invention.

Fig. 11 is a second schematic structural view of the stirring mechanism 2 of the road concrete paving device of the present invention.

Fig. 12 is a third schematic structural view of the stirring mechanism 2 of the road concrete paving device of the present invention.

Fig. 13 is a fourth schematic structural view of the stirring mechanism 2 of the road concrete paving device of the present invention.

Fig. 14 is a first structural schematic diagram of a frame mechanism 3 of the road concrete paving device of the present invention.

Fig. 15 is a second structural schematic diagram of the frame mechanism 3 of the road concrete paving device of the present invention.

Fig. 16 is a third structural schematic view of the frame mechanism 3 of the road concrete paving device of the present invention.

In the figure: a body mechanism 1; 1-1 of a hydraulic cylinder; a piston rod 1-2; 1-3 of a light hole; 1-4 of a base; 1-5 slide bars; 1-6 of a spring; 1-7 of a floating stirring box; 1-8 parts of a limiting block with holes; 1-9 parts of a seat with a hole; a piston rod I1-10; support shells 1-11; 1-12 parts of a cross groove; 1-13 parts of spring; 1-14 parts of a limiting rod; a feed buffer tank 1-15; 1-16 of a water inlet one-way valve; feed ports 1-17; a feed slide box 1-18; a stepped groove seat A1-19; switching hydraulic cylinders 1-20; 1-21 of servo motor; 1-22 of a coupler; 1-23 parts of a screw rod; slide rails 1-24; a step slide block I1-25; articulated arms 1-26; intermediate connecting seats 1-27; 1-28 of a portal support with holes; 1-29 parts of limiting spring; connecting plates I1-30; a switch lever 1-31; a built-in slide bar 1-32; springs 1-33 are built in; a piston rod II 1-34; 1-35 of a gate; 1-36 of a gate slot; sliding the discharge pipe 1-37; mating ports 1-38; bidirectional hydraulic cylinders 1-39; bar A1-40; springs B1-41; inner grooves 1-42; a stirring mechanism 2; 2-1 of a special-shaped bearing seat; a motor 2-2; 2-3 of a belt; 2-4 of a motor belt pulley; belt shaft transmission belt pulleys 2-5; pulley A2-6; belt A2-7; 2-8 parts of a special-shaped sliding seat; belt pulleys 2-9 with grooves; 2-10 parts of an L-shaped seat; perforated base I2-11; 2-12 of a slide block with a hole; a chute A2-13; 2-14 parts of an impeller; 2-15 parts of an impeller shaft; 2-16 of a vibration spring; 2-17 of a vibration limiting rod; a bidirectional hydraulic cylinder A2-18; a piston rod III 2-19; a limiting rod I2-20; 2-21 parts of vertical sliding holes; 2-22 transverse limiting holes; a frame mechanism 3; a moving wheel 3-1; a frame body 3-2; 3-3 of a movable support rod; a support shell I3-4; 3-5 of a scraper with a gear; 3-6 of a sliding rack; a lead screw I3-7; bearing seat A3-8; a servo motor A3-9; a limiting groove I3-10.

Detailed Description

The first embodiment is as follows:

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, fig. 13, fig. 14, fig. 15, and fig. 16, and the present invention relates to a paving apparatus, and more specifically, to a road concrete paving apparatus, including a machine body mechanism 1, a stirring mechanism 2, and a frame mechanism 3, the apparatus being capable of dust-free feeding, stirring, multi-dimensional stirring, and switching to a discharge mode.

The machine body mechanism 1 is connected with the stirring mechanism 2, and the machine body mechanism 1 is connected with the frame mechanism 3.

The second embodiment is as follows:

the following describes the present embodiment 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, fig. 14, fig. 15, fig. 16, and the present embodiment further describes the present embodiment, where the machine body mechanism 1 includes a hydraulic cylinder 1-1, a piston rod 1-2, a unthreaded hole 1-3, a base 1-4, a sliding rod 1-5, a spring 1-6, a floating agitator tank 1-7, a limiting block with holes 1-8, a seat with holes 1-9, a piston rod I1-10, a support shell 1-11, a cross groove 1-12, a spring 1-13, a limiting rod 1-14, a feed buffer tank 1-15, a one-way valve for water feeding 1-16, a feed port 1-17, a feed slide tank 1-18, a seat with a step groove a1-19, a stepped groove seat, 1-20 switching hydraulic cylinders, 1-21 servo motors, 1-22 couplings, 1-23 lead screws, 1-24 sliding rails, I1-25 step sliders, 1-26 articulated arms, 1-27 intermediate connecting seats, 1-28 holed gate type supports, 1-29 limiting springs, I1-30 connecting plates, 1-31 switching rods, 1-32 built-in sliding rods, 1-33 built-in springs, 1-34 piston rods II1-34, 1-35 gates, 1-36 gate slots, 1-37 sliding discharge pipes, 1-38 matching ports, 1-39 bidirectional hydraulic cylinders, A1-40 rods, B1-41 internal slots and 1-42 internal slots, 1-1 hydraulic cylinders are connected with 1-2 piston rods, 1-2 piston rods are connected with 1-4 bases, 1-4 bases are provided with unthreaded holes 1-3, a base 1-4 is connected with a sliding rod 1-5, a spring 1-6 is sleeved on the sliding rod 1-5, the spring 1-6 is abutted against the base 1-4 and a floating stirring box 1-7, the floating stirring box 1-7 is connected with the sliding rod 1-5 in a sliding way, the sliding rod 1-5 is connected with a limiting block with a hole 1-8, the floating stirring box 1-7 is connected with a seat with a hole 1-9, the limiting block with a hole 1-8 is connected with a piston rod I1-10 in a sliding way, the piston rod I1-10 is connected with the seat with a hole 1-9 in a sliding way, the piston rod I1-10 is connected with a bidirectional hydraulic cylinder 1-39, the bidirectional hydraulic cylinder 1-39 is connected with a supporting shell 1-11, the supporting shell 1-11 is connected with the floating stirring box 1-7, cross grooves 1-12 are symmetrically arranged on, the springs 1-13 are sleeved on the limiting rods 1-14, the limiting rods 1-14 are connected with the floating stirring boxes 1-7, the floating stirring boxes 1-7 are connected and communicated with the feeding buffer boxes 1-15, the water inlet one-way valves 1-16 are connected with the feeding buffer boxes 1-15, the feeding buffer boxes 1-15 are provided with the feeding ports 1-17, the feeding ports 1-17 are slidably connected with the feeding sliding boxes 1-18, the feeding sliding boxes 1-18 are slidably connected with the rods A1-40, the springs B1-41 are sleeved on the rods A1-40, the springs B1-41 are abutted against the feeding sliding boxes 1-18 and the feeding ports 1-17, the inner grooves 1-42 are arranged on the feeding ports 1-17, the inner grooves 1-42 are slidably connected with the feeding sliding boxes 1-18, the stepped groove seats A1-19 are connected with the floating stirring boxes 1-7, a groove seat A1-19 with steps is connected with a switching hydraulic cylinder 1-20, a servo motor 1-21 is connected with a floating stirring box 1-7, the servo motor 1-21 is connected with a lead screw 1-23 through the lead screw 1-23, the lead screw 1-23 is connected with a slide rail 1-24 in a bearing way, the slide rail 1-24 is connected with the floating stirring box 1-7, the lead screw 1-23 is connected with a step slide block I1-25 in a threaded way, the step slide block I1-25 is connected with the slide rail 1-24 in a sliding way, the step slide block I1-25 is hinged with a hinged arm 1-26, the hinged arm 1-26 is hinged with an intermediate connecting seat 1-27, the intermediate connecting seat 1-27 is connected with a support 1-28 with holes in a sliding way, the support 1-28 with holes is connected with the floating stirring box 1-, limiting springs 1-29 are sleeved on intermediate connecting seats 1-27, the intermediate connecting seats 1-27 are connected with connecting plates I1-30, the connecting plates I1-30 are connected with connecting plates I1-30, switching rods 1-31 are slidably connected with floating stirring boxes 1-7, built-in sliding rods 1-32 are connected with stepped groove seats A1-19, built-in springs 1-33 are sleeved on the built-in sliding rods 1-32, switching hydraulic cylinders 1-20 are connected with piston rods II1-34, piston rods II1-34 are connected with gates 1-35, the gates 1-35 are slidably connected with gate grooves 1-36, the gate grooves 1-36 are arranged on sliding discharge pipes 1-37, sliding discharge pipes 1-37 are connected and communicated with the floating stirring boxes 1-7, the sliding discharge pipes 1-37 are slidably connected with matching ports 1-38, the matching ports 1-38 are arranged on the bases 1-4, before the device is used, a water pipe is externally connected to the positions of the water inlet check valves 1-16, then high-pressure water is injected, the water can rush the water inlet check valves 1-16 to enter the feeding buffer boxes 1-15, then cement raw materials are synchronously added to the positions of the feeding sliding boxes 1-18, the raw materials move downwards under the action of gravity to impact the feeding sliding boxes 1-18 and then downwards enter the feeding buffer boxes 1-15, in the process, the springs B1-41 are compressed, then the springs B1-41 rebound to drive the feeding buffer boxes 1-15 to reset, so that the feeding buffer boxes 1-15 are vibrated, feeding is enabled to be more, in the process, the high-pressure water forms negative pressure, dust is smoothly sucked into the feeding buffer boxes 1-15, thus, the dust can be prevented from diffusing outwards, and the environmental protection is ensured.

The third concrete implementation mode:

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, fig. 14, fig. 15, fig. 16, and the embodiment further describes the embodiment, where the stirring mechanism 2 includes a special-shaped bearing seat 2-1, a motor 2-2, a belt 2-3, a motor pulley 2-4, a belt shaft transmission pulley 2-5, a pulley a2-6, a belt a2-7, a special-shaped sliding seat 2-8, a belt pulley 2-9, an L-shaped seat 2-10, a perforated seat I2-11, a perforated slider 2-12, a chute a2-13, an impeller 2-14, an impeller shaft 2-15, a vibrating spring 2-16, a vibrating limiting rod 2-17, a bidirectional hydraulic cylinder a2-18, a bidirectional hydraulic cylinder a, A piston rod III2-19, a limiting rod I2-20, a vertical sliding hole 2-21 and a horizontal limiting hole 2-22, wherein a special-shaped bearing seat 2-1 is connected with a stepped groove seat A1-19 in a sliding way, a special-shaped bearing seat 2-1 is connected with an internal sliding rod 1-32 in a sliding way, an internal spring 1-33 is propped against the special-shaped bearing seat 2-1, the special-shaped bearing seat 2-1 is connected with a motor 2-2, the motor 2-2 is connected with a motor belt pulley 2-4, the motor belt pulley 2-4 is connected with a belt 2-3 in a friction way, the belt 2-3 is connected with a belt shaft transmission belt pulley 2-5 in a friction way, the belt shaft transmission belt pulley 2-5 is connected with the special-shaped bearing seat 2-1 in a bearing way, the belt shaft transmission belt pulley 2-5 is, the belt pulley A2-6 is in frictional connection with a belt A2-7, the belt A2-7 is in frictional connection with a belt pulley 2-9 with a groove, the L-shaped seat 2-10 is connected with a piston rod III2-19, the piston rod III2-19 is connected with a bidirectional hydraulic cylinder A2-18, the bidirectional hydraulic cylinder A2-18 is connected with a special-shaped sliding seat 2-8, the special-shaped sliding seat 2-8 is connected with the impeller shaft 2-15 through a bearing, the special-shaped sliding seat 2-8 is in sliding connection with a cross groove 1-12, the special-shaped sliding seat 2-8 is provided with a vertical sliding hole 2-21 and a transverse limiting hole 2-22, the vertical sliding hole 2-21 is in sliding connection with a limiting rod 1-14, the transverse limiting hole 2-22 is in sliding connection with a switching rod 1-31, the L-shaped seat 2-10 is connected with a limiting rod I39, the limiting rod I2-20 is connected with a perforated seat I2-11 in a sliding way, the perforated seat I2-11 is connected with a belt pulley with a groove 2-9, the limiting rod I2-20 is connected with a sliding block with a hole 2-12 in a sliding way, the sliding block with a hole 2-12 is connected with a sliding groove A2-13 in a sliding way, an impeller 2-14 is connected with an impeller shaft 2-15, a vibration spring 2-16 is sleeved on the vibration limiting rod 2-17, the vibration limiting rod 2-17 is connected with the belt pulley with a groove 2-9, the vibration limiting rod 2-17 is connected with the sliding block with a hole 2-12 in a sliding way, the limiting rod I2-20 is connected with the sliding block with a hole 2-12 in a sliding way, the motor pulley 2-4 is driven to rotate by the operation of a motor 2-2, the motor pulley 2-4 is driven to drive the belt pulley A2-, the belt pulley A2-6 drives the belt grooved pulley 2-9 to rotate through the belt A2-7, the belt grooved pulley 2-9 drives the impeller 2-14 to rotate through the impeller shaft 2-15, the impeller 2-14 rotates to stir cement raw materials and water, the servo motor 1-21 operates to drive the coupler 1-22 to rotate clockwise when viewed from top to bottom, the coupler 1-22 drives the lead screw 1-23 to rotate, the lead screw 1-23 drives the step slide block I1-25 to slide downwards, the step slide block I1-25 pushes the intermediate connecting seat 1-27 through the hinged arm 1-26, the intermediate connecting seat 1-27 pulls the switching rod 1-31 through the connecting plate I1-30, and the switching rod 1-31 is separated from the transverse limiting hole 2-22, then a bidirectional hydraulic cylinder A2-18 drives a piston rod III2-19 to push an L-shaped seat 2-10, so that the L-shaped seat 2-10 drives a limiting rod I2-20 to be separated from a perforated slide block 2-12, the perforated slide block 2-12 deviates to one side due to centrifugal force when a grooved belt pulley 2-9 rotates, the grooved belt pulley 2-9 forms a deviation force in rotation, the special-shaped sliding seat 2-8 reciprocates up and down under the cooperation of a spring 1-13, and the special-shaped sliding seat 2-8 drives a rotating impeller 2-14 to reciprocate up and down, so that multi-dimensional stirring is realized.

The fourth concrete implementation mode:

the following describes the present embodiment 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, fig. 14, fig. 15, and fig. 16, and the present embodiment further describes the present embodiment, where the carriage mechanism 3 includes a moving wheel 3-1, a carriage body 3-2, a moving support rod 3-3, a support housing I3-4, a toothed scraper 3-5, a sliding rack 3-6, a screw I3-7, a bearing seat A3-8, a servo motor A3-9, and a limit groove I3-10, the moving wheel 3-1 is connected to the carriage body 3-2 by a bearing, the carriage body 3-2 is connected to the moving support rod 3-3, the moving support rod 3-3 is connected to the unthreaded hole 1-3 in a sliding manner, a support shell I3-4 is arranged on a frame body 3-2, the support shell I3-4 is in sliding connection with a hydraulic cylinder 1-1, a piston rod 1-2 is in sliding connection with the frame body 3-2, a toothed wheel scraper 3-5 is hinged with the frame body 3-2, the toothed wheel scraper 3-5 is meshed with a sliding rack 3-6, the sliding rack 3-6 is in sliding connection with a limit groove I3-10, the limit groove I3-10 is arranged on the frame body 3-2, the sliding rack 3-6 is in threaded connection with a lead screw I3-7, the lead screw I3-7 is in bearing connection with a bearing seat A3-8, the bearing seat A3-8 is connected with the frame body 3-2, the lead screw I3-7 is connected with a servo motor A3-9, the servo motor A3-9 is connected with the frame body 3-2, when the unloading mode needs to be switched, firstly, the servo motor 1-21 is operated in the reverse direction to drive the switching rod 1-31 to be inserted into the transverse limiting hole 2-22 again, then the piston rod I1-10 is pulled through the bidirectional hydraulic cylinder 1-39, the piston rod I1-10 can be separated from the limiting block with the hole 1-8, thus under the coordination of the bias force and the spring 1-6, the whole floating stirring box 1-7 can vibrate up and down, then the hydraulic cylinder 1-20 is switched to drive the piston rod II1-34 to move, the piston rod II1-34 can pull the gate 1-35 to move, so that the stirred cement can be vibrated and poured out from the sliding discharging pipe 1-37 to finish unloading, in the process, the servo motor A3-9 alternately operates in the forward and reverse directions to drive the screw rod I3-7 to rotate back and forth, the screw I3-7 drives the sliding rack 3-6 to reciprocate, and the sliding rack 3-6 drives the scraper with the gear 3-5 to reciprocate, so that the concrete is scraped.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, and 16, and the first embodiment will be further described with reference to the present embodiment, in which the impeller 2 to 14 is made of high manganese steel.

The working principle of the device is as follows: the device can feed dust-free materials, before the device is used, a water pipe is externally connected to the position of a water inlet one-way valve 1-16, then high-pressure water is injected, the water can flush the water inlet one-way valve 1-16 and enter a feeding buffer box 1-15, then cement raw materials are synchronously added to the position of a feeding sliding box 1-18, the raw materials move downwards under the action of gravity to impact the feeding sliding box 1-18 and then downwards enter the feeding buffer box 1-15, a spring B1-41 is compressed in the process, then the spring B1-41 rebounds to drive the feeding buffer box 1-15 to reset, so that the feeding buffer box 1-15 is vibrated, the feeding is smoother, in the process, the high-pressure water forms negative pressure, dust is sucked into the feeding buffer box 1-15, and the dust is prevented from diffusing outwards, thereby ensuring environmental protection; the device can stir, the motor belt pulley 2-4 is driven to rotate by the operation of the motor 2-2, the motor belt pulley 2-4 can drive the belt pulley A2-6 to rotate by the transmission of the belt 2-3 and the belt shaft transmission belt pulley 2-5, the belt pulley A2-6 can drive the belt pulley 2-9 with a groove to rotate by the belt A2-7, the belt pulley 2-9 with a groove can drive the impeller 2-14 to rotate by the impeller shaft 2-15, and the impeller 2-14 can stir cement raw materials and water by the rotation of the impeller 2-14; the device can perform multidimensional stirring, the servo motors 1-21 operate to drive the couplers 1-22 to rotate clockwise when viewed from top to bottom, the couplers 1-22 drive the lead screws 1-23 to rotate, the lead screws 1-23 drive the step sliders I1-25 to slide downwards, the step sliders I1-25 push the intermediate connecting seats 1-27 through the hinged arms 1-26, the intermediate connecting seats 1-27 pull the switching rods 1-31 through the connecting plates I1-30 to separate the switching rods 1-31 from the transverse limiting holes 2-22, then the bidirectional hydraulic cylinders A2-18 drive the piston rods III2-19 to push the L-shaped seats 2-10, so that the L-shaped seats 2-10 drive the limiting rods I2-20 to separate from the perforated sliders 2-12, and therefore when the grooved belt pulleys 2-9 rotate, the perforated slide blocks 2-12 deflect to one side due to centrifugal force, so that the belt grooved pulleys 2-9 form a deflection force in rotation, the special-shaped sliding seats 2-8 reciprocate up and down under the cooperation of the springs 1-13, and the special-shaped sliding seats 2-8 drive the rotating impellers 2-14 to reciprocate up and down, so that multidimensional stirring is realized; the device can be switched to a discharging mode, when the device needs to be switched to the discharging mode, firstly, the servo motors 1-21 are operated in a reverse direction to drive the switching rods 1-31 to be inserted into the transverse limiting holes 2-22 again, then the piston rods I1-10 are pulled through the bidirectional hydraulic cylinders 1-39, the piston rods I1-10 can be separated from the limiting blocks 1-8 with holes, so that under the coordination of the biasing force and the springs 1-6, the whole floating stirring box 1-7 can vibrate up and down, then the hydraulic cylinders 1-20 are switched to drive the piston rods II1-34 to move, the piston rods II1-34 can pull the gates 1-35 to move, the stirred cement can be discharged from the sliding discharging pipes 1-37 in a vibrating mode to finish discharging, in the process, the servo motors A3-9 alternately operate in a forward and reverse direction and a reverse direction to drive the screw rods I3-, the screw I3-7 drives the sliding rack 3-6 to reciprocate, and the sliding rack 3-6 drives the scraper with the gear 3-5 to reciprocate, so that the concrete is scraped.

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 (5)

1. The utility model provides a road concrete laying device, includes fuselage mechanism (1), rabbling mechanism (2), frame mechanism (3), its characterized in that: the machine body mechanism (1) is connected with the stirring mechanism (2), and the machine body mechanism (1) is connected with the frame mechanism (3).

2. A road concrete laying apparatus according to claim 1 wherein: the machine body mechanism (1) comprises a hydraulic cylinder (1-1), a piston rod (1-2), a unthreaded hole (1-3), a base (1-4), a sliding rod (1-5), a spring (1-6), a floating stirring box (1-7), a hole-containing limiting block (1-8), a hole-containing seat (1-9), a piston rod I (1-10), a supporting shell (1-11), a cross groove (1-12), a spring (1-13), a limiting rod (1-14), a feeding buffer box (1-15), a water inlet one-way valve (1-16), a feeding port (1-17), a feeding sliding box (1-18), a stepped groove seat A (1-19), a switching hydraulic cylinder (1-20), a servo motor (1-21), a coupler (1-22), The device comprises a lead screw (1-23), slide rails (1-24), a step slide block I (1-25), an articulated arm (1-26), an intermediate connecting seat (1-27), a perforated gate type support (1-28), a limiting spring (1-29), a connecting plate I (1-30), a switching rod (1-31), a built-in slide rod (1-32), a built-in spring (1-33), a piston rod II (1-34), a gate (1-35), a gate groove (1-36), a sliding discharge pipe (1-37), a matching port (1-38), a bidirectional hydraulic cylinder (1-39), a rod A (1-40), a spring B (1-41) and an inner groove (1-42), wherein the hydraulic cylinder (1-1) is connected with the piston rod (1-2), and the piston rod (1-2) is connected with a base (1-4), a base (1-4) is provided with a unthreaded hole (1-3), the base (1-4) is connected with a sliding rod (1-5), a spring (1-6) is sleeved on the sliding rod (1-5), the spring (1-6) is propped against the base (1-4) and a floating stirring box (1-7), the floating stirring box (1-7) is connected with the sliding rod (1-5) in a sliding way, the sliding rod (1-5) is connected with a limiting block (1-8) with a hole, the floating stirring box (1-7) is connected with a seat (1-9) with a hole, the limiting block (1-8) with a hole is connected with a piston rod I (1-10) in a sliding way, the piston rod I (1-10) is connected with the seat (1-9) with a hole, the piston rod I (1-10) is connected with a bidirectional hydraulic cylinder (1-39), the bidirectional hydraulic cylinder (1-39) is connected with the supporting shell (1-11), the supporting shell (1-11) is connected with the floating stirring box (1-7), the cross slots (1-12) are symmetrically arranged on the floating stirring box (1-7), the spring (1-13) is sleeved on the limiting rod (1-14), the limiting rod (1-14) is connected with the floating stirring box (1-7), the floating stirring box (1-7) is connected and communicated with the feeding buffer box (1-15), the water inlet one-way valve (1-16) is connected with the feeding buffer box (1-15), the feeding buffer box (1-15) is provided with a feeding port (1-17), the feeding port (1-17) is connected with the feeding sliding box (1-18) in a sliding way, the feeding sliding box (1-18) is connected with the rod A (1-40) in a sliding way, the spring B (1-41) is sleeved on the rod A (1-40), the spring B (1-41) is abutted against the feeding sliding box (1-18) and the feeding port (1-17), the inner groove (1-42) is arranged on the feeding port (1-17), the inner groove (1-42) is in sliding connection with the feeding sliding box (1-18), the groove seat A (1-19) with steps is connected with the floating stirring box (1-7), the groove seat A (1-19) with steps is connected with the switching hydraulic cylinder (1-20), the servo motor (1-21) is connected with the floating stirring box (1-7), the servo motor (1-21) is connected with the lead screw (1-23) through the lead screw (1-23), the lead screw (1-23) is connected with the sliding rail (1-24) in a bearing way, the slide rails (1-24) are connected with the floating stirring box (1-7), the lead screws (1-23) are in threaded connection with the step slide blocks I (1-25), the step slide blocks I (1-25) are in sliding connection with the slide rails (1-24), the step slide blocks I (1-25) are hinged with the hinged arms (1-26), the hinged arms (1-26) are hinged with the intermediate connecting seats (1-27), the intermediate connecting seats (1-27) are in sliding connection with the perforated door-shaped supports (1-28), the perforated door-shaped supports (1-28) are connected with the floating stirring box (1-7), the limiting springs (1-29) are sleeved on the intermediate connecting seats (1-27), the intermediate connecting seats (1-27) are connected with the connecting plates I (1-30), the connecting plates I (1-30) are connected with the connecting plates I (1-30), the switching rod (1-31) is connected with the floating stirring box (1-7) in a sliding mode, the built-in sliding rod (1-32) is connected with the groove seat A (1-19) with steps, the built-in spring (1-33) is sleeved on the built-in sliding rod (1-32), the switching hydraulic cylinder (1-20) is connected with the piston rod II (1-34), the piston rod II (1-34) is connected with the gate (1-35), the gate (1-35) is connected with the gate groove (1-36) in a sliding mode, the gate groove (1-36) is arranged on the sliding discharge pipe (1-37), the sliding discharge pipe (1-37) is connected and communicated with the floating stirring box (1-7), the sliding discharge pipe (1-37) is connected with the matching opening (1-38) in a sliding mode, and the matching opening (1-38) is arranged on the base (1-4).

3. A road concrete laying apparatus according to claim 1 wherein: the stirring mechanism (2) comprises a special-shaped bearing seat (2-1), a motor (2-2), a belt (2-3), a motor belt pulley (2-4), a belt shaft transmission belt pulley (2-5), a belt pulley A (2-6), a belt A (2-7), a special-shaped sliding seat (2-8), a belt groove belt pulley (2-9), an L-shaped seat (2-10), a belt hole seat I (2-11), a belt hole sliding block (2-12), a sliding groove A (2-13), an impeller (2-14), an impeller shaft (2-15), a vibration spring (2-16), a vibration limiting rod (2-17), a bidirectional hydraulic cylinder A (2-18), a piston rod III (2-19), a limiting rod I (2-20), a vertical sliding hole (2-21), A transverse limiting hole (2-22), a special-shaped bearing seat (2-1) is connected with a stepped groove seat A (1-19) in a sliding manner, a special-shaped bearing seat (2-1) is connected with a built-in slide rod (1-32) in a sliding manner, a built-in spring (1-33) abuts against the special-shaped bearing seat (2-1), the special-shaped bearing seat (2-1) is connected with a motor (2-2), the motor (2-2) is connected with a motor belt pulley (2-4), the motor belt pulley (2-4) is connected with a belt (2-3) in a friction manner, the belt (2-3) is connected with a belt shaft transmission belt pulley (2-5) in a friction manner, the belt shaft transmission belt pulley (2-5) is connected with the special-shaped bearing seat (2-1) in a bearing manner, and the belt shaft transmission belt pulley (2-5) is connected with a belt pulley A (, the belt pulley A (2-6) is in friction connection with the belt A (2-7), the belt A (2-7) is in friction connection with the belt pulley with a groove (2-9), the L-shaped seat (2-10) is connected with the piston rod III (2-19), the piston rod III (2-19) is connected with the bidirectional hydraulic cylinder A (2-18), the bidirectional hydraulic cylinder A (2-18) is connected with the special-shaped sliding seat (2-8), the special-shaped sliding seat (2-8) is connected with the impeller shaft (2-15) in a bearing mode, the special-shaped sliding seat (2-8) is in sliding connection with the cross groove (1-12), the special-shaped sliding seat (2-8) is provided with a vertical sliding hole (2-21) and a transverse limiting hole (2-22), and the vertical sliding hole (2-21) is in sliding connection with the limiting rod (1-14), the transverse limiting holes (2-22) are connected with the switching rods (1-31) in a sliding manner, the L-shaped seats (2-10) are connected with limiting rods I (2-20), the limiting rods I (2-20) are connected with perforated seats I (2-11) in a sliding manner, the perforated seats I (2-11) are connected with belt grooved pulleys (2-9), the limiting rods I (2-20) are connected with perforated sliders (2-12) in a sliding manner, the perforated sliders (2-12) are connected with sliding chutes A (2-13) in a sliding manner, impellers (2-14) are connected with impeller shafts (2-15), vibration springs (2-16) are sleeved on the vibration limiting rods (2-17), the vibration limiting rods (2-17) are connected with the belt grooved pulleys (2-9), the vibration limiting rods (2-17) are connected with the perforated sliders (2-12) in a sliding manner, the limiting rod I (2-20) is connected with the slide block (2-12) with the hole in a sliding way.

4. A road concrete laying apparatus according to claim 1 wherein: the frame mechanism (3) comprises a moving wheel (3-1), a frame body (3-2), a moving support rod (3-3), a support shell I (3-4), a scraper with a gear (3-5), a sliding rack (3-6), a screw rod I (3-7), a bearing seat A (3-8), a servo motor A (3-9) and a limit groove I (3-10), wherein the moving wheel (3-1) is connected with the frame body (3-2) in a bearing manner, the frame body (3-2) is connected with the moving support rod (3-3), the moving support rod (3-3) is connected with the unthreaded hole (1-3) in a sliding manner, the frame body (3-2) is provided with the support shell I (3-4), and the support shell I (3-4) is connected with a hydraulic cylinder (1-1) in a sliding manner, the piston rod (1-2) is connected with the frame body (3-2) in a sliding mode, the scraper plate with the gear (3-5) is hinged with the frame body (3-2), the scraper plate with the gear (3-5) is meshed with the sliding rack (3-6), the sliding rack (3-6) is connected with the limiting groove I (3-10) in a sliding mode, the limiting groove I (3-10) is arranged on the frame body (3-2), the sliding rack (3-6) is connected with the lead screw I (3-7) in a threaded mode, the lead screw I (3-7) is connected with the bearing seat A (3-8) in a bearing mode, the bearing seat A (3-8) is connected with the frame body (3-2), the lead screw I (3-7) is connected with the servo motor A (3-9), and the servo motor A (3-9) is connected with the frame body (3-2).

5. A road concrete laying apparatus according to claim 3 wherein: the impeller (2-14) is made of high manganese steel.

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