CN108127766B - Improved multifunctional pouring, tamping and trowelling vibration system - Google Patents

Abstract

The invention provides an improved multifunctional pouring, tamping and trowelling vibration system, and belongs to the technical field of machinery. It has solved the poor problem of prior art stability. The utility model provides a multi-functional vibrating system that casts of this improvement, multi-functional vibrating system that casts of screeds includes a frame, the frame bottom has the gyro wheel, and frame upper portion has the hopper, and hopper upper portion is the feed inlet, and the hopper lower part is discharge gate and discharge gate is close to frame front portion department, the frame rear portion has vibration mechanism, still has the material mechanism of driving between above-mentioned vibration mechanism and the hopper discharge gate. The multifunctional pouring, tamping and trowelling vibration system of the improvement is high in stability.

Description

Improved multifunctional pouring, tamping and trowelling vibration system

Technical Field

The invention belongs to the technical field of machinery, and relates to an improved multifunctional pouring, tamping and trowelling vibration system.

Background

The precast pile needs to be screeded with the concrete raw materials on the moulded die in the manufacturing process, and current screeding operation is usually manual operation implementation, and its work efficiency is lower, wastes time and energy, intensity of labour is big.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provide an improved multifunctional pouring, tamping and trowelling vibration system which is compact in structure and high in stability.

The aim of the invention can be achieved by the following technical scheme:

the utility model provides a multi-functional pouring, tamping and trowelling vibration system of improvement, multi-functional pouring, tamping and trowelling vibration system includes a frame, its characterized in that, the frame bottom has the gyro wheel, and frame upper portion has the hopper, and hopper upper portion is the feed inlet, and the hopper lower part is the discharge gate and the discharge gate is close to frame front portion department, the frame rear portion has vibration mechanism, still has the material mechanism of driving between above-mentioned vibration mechanism and the hopper discharge gate.

In the above-mentioned multi-functional vibration system that casts of improvement, catch up with material mechanism includes fixing base one, fixing base two, catch up with material driving piece, swing arm and catch up with the material axle, and above-mentioned fixing base one and fixing base two all link firmly in the frame, and above-mentioned catch up with the material driving piece links firmly on fixing base one, and above-mentioned swing arm inner articulates in catch up with the material axle, and above-mentioned catch up with the material axle axial and link firmly in swing arm outer end department, have transmission structure between above-mentioned catch up with the material driving piece and catch up with the material axle, and above-mentioned catch up with the material driving piece and can drive to catch up with the material axle through transmission structure and rotate.

The material driving mechanism is creatively fixed on the frame through the first fixing seat, and the material driving part is firmly fixed on the frame. The inner end of the swing arm is stably hinged on the frame through the second fixing seat.

When the construction operation of driving the material is carried out, the driving piece drives the driving shaft to rotate through the transmission structure, and the rotating driving shaft smoothes the concrete raw material on the upper part of the forming die.

Meanwhile, as the inner ends of the swing arms are hinged to the two rows of the fixing base, the material driving shaft can swing in a proper small amplitude when in material driving operation, and therefore the material driving performance of the material driving shaft is further improved.

In the improved multifunctional pouring, tamping and leveling vibration system, the material driving part is a motor, and the motor is fixedly connected to the first fixing seat.

In the above-mentioned multi-functional pouring and tamping screeding vibration system of improvement, fixing base two includes the base and is cylindric connecting portion in base upper portion, and above-mentioned base passes through the fastener and links firmly in the frame, and above-mentioned swing arm inner articulates in the connecting portion outside, and the pivot of above-mentioned motor is located connecting portion department.

The inner end of the swing arm can be stably hinged to the second fixing seat through the connecting part, and the second fixing seat can be stably and fixedly connected to the frame through the base.

In the improved multifunctional pouring, tamping and leveling vibration system, a bearing is arranged between the motor rotating shaft and the connecting part.

In the improved multifunctional pouring, tamping and leveling vibration system, the outer end of the swing arm is provided with a cylindrical positioning cylinder, and the end part of the material driving shaft is axially fixedly connected in the positioning cylinder.

The material driving shaft can be stably and axially fixedly connected to the outer end of the swing arm through the positioning cylinder.

In the improved multifunctional pouring, tamping and leveling vibration system, a bearing is arranged between the end part of the material driving shaft and the positioning cylinder.

The material driving shaft can smoothly rotate under the action of the bearing.

In the improved multifunctional pouring, tamping and leveling vibration system, the driving wheel is fixedly connected to the rotating shaft of the motor, the driven wheel is fixedly connected to the end part of the material driving shaft, and the driving wheel is connected with the driven wheel.

In the improved multifunctional pouring, tamping and leveling vibration system, the driving wheel and the driven wheel are both chain wheels, and the driving wheel is connected with the driven wheel through a transmission chain.

In the improved multifunctional pouring, tamping and leveling vibration system, the driving wheel and the driven wheel are belt wheels and are connected through a transmission belt.

In the improved multifunctional pouring, tamping and trowelling vibration system, the first fixing seat, the second fixing seat, the material driving piece and the swing arm form a driving unit, the number of the driving units is two, and the two driving units are respectively positioned at two ends of the material driving shaft.

The driving shaft is driven to rotate by the two driving units to have two functions:

firstly, as the two ends of the material driving shaft are connected, the connection stability of the material driving shaft can be ensured;

Secondly, because two drive units can both drive the rotation of driving the material axle, consequently, drive the rotation in-process power of material axle powerful, can effectively improve and drive the material effect.

In the multifunctional pouring, tamping and leveling vibration system of the improvement, the vibration mechanism comprises a vibration frame, a vibration seat, a vibration driving piece and a transmission shaft, wherein the vibration frame is in a strip shape, the vibration seat is uniformly distributed along the length direction of the vibration frame, the transmission shaft is connected with the vibration driving piece and can drive the transmission shaft to rotate, the transmission shaft is axially fixedly connected with the vibration seat, and an eccentric pendulum is fixedly connected on the transmission shaft.

The transmission shaft is provided with a plurality of eccentric pendulums which are uniformly distributed along the axial direction of the transmission shaft.

All eccentric pendulums are driven to rotate by the same vibration driving piece, and the non-center positions of the eccentric pendulums are connected to the transmission shaft. Therefore, the eccentric pendulum bob can drive the vibration frame to vibrate, so that the vibration tamping is realized on the concrete raw materials on the forming die.

In the above-mentioned multi-functional pouring, tamping and trowelling vibration system of improvement, the vibration frame includes underframe, crossbeam and bracing piece, and above-mentioned underframe is square frame form, and above-mentioned crossbeam is located underframe upper portion, and the quantity of above-mentioned bracing piece is a plurality of and the both ends of bracing piece link firmly respectively on crossbeam and underframe.

Such a structure can reduce the weight of the entire vibration frame and can ensure the strength of the vibration frame itself.

In the improved multifunctional pouring, tamping and trowelling vibration system, the cross beam is arranged in parallel with the bottom frame, is positioned at the center of the bottom frame, and the left side and the right side of the cross beam are respectively provided with a support rod.

Thus, not only the compactness of the structure can be improved, but also the strength is higher.

In the improved multifunctional pouring, tamping and leveling vibration system, the support rod comprises a first rod body and a second rod body, two ends of the first rod body and the second rod body are fixedly connected to the cross beam and the bottom frame, and the upper ends of the first rod body and the second rod body are intersected and an included angle between the first rod body and the second rod body is 60-120 degrees.

This structure can ensure that the vibration frame has sufficient strength.

In the improved multifunctional pouring, tamping and trowelling vibration system, the support rods symmetrically arranged are arranged at the left side and the right side of the cross beam, the two groups of support rods form a support unit, the number of the support units is a plurality, and the support units are uniformly distributed along the length direction of the cross beam.

In the improved multifunctional pouring, tamping and leveling vibration system, the end part of the bottom frame is further provided with a rod body III, the rod body III is vertically arranged with the bottom frame, the lower end of the rod body III is fixedly connected with the bottom frame, and the upper end of the rod body III is fixedly connected with the cross beam.

This can improve the compactness of the end of the vibration frame.

In the improved multifunctional pouring, tamping and leveling vibration system, two sides of the rod body III are provided with the rod body IV and the rod body V, the upper ends of the rod body IV and the rod body V are fixedly connected to the cross beam, the lower end of the rod body IV is fixedly connected to the edge of the bottom frame, and the lower end of the rod body V is fixedly connected to the other edge of the bottom frame.

Therefore, the end part of the vibration frame can be ensured to have enough strength, and the end part structure compactness of the vibration frame can be improved.

In the improved multifunctional pouring, tamping and leveling vibration system, the fourth rod body and the fifth rod body are symmetrically arranged by taking the third rod body as a reference.

In the improved multifunctional pouring, tamping and leveling vibration system, the rod body six in a rod shape is fixedly connected to the upper portion of the bottom frame, and the lower end of the vibration seat is fixedly connected to the rod body six.

The vibration seat can be stably and fixedly connected to the bottom frame through the rod body six.

In the improved multifunctional pouring, tamping and trowelling vibration system, the upper end of the vibration seat is sleeved on the transmission shaft, and a bearing is arranged between the vibration seat and the transmission shaft.

In the improved multifunctional pouring, tamping and leveling vibration system, the eccentric pendulum is disc-shaped, and the vertical edge of the eccentric pendulum is fixedly connected to the transmission shaft.

Compared with the prior art, the improved multifunctional pouring, tamping and trowelling vibration system has the advantages that the material driving shaft can slightly swing during construction operation, so that the material driving effect during construction operation can be properly improved.

Meanwhile, as the two driving units are respectively connected with the two ends of the material driving shaft, the material driving effect can be further improved.

In addition, the first fixing seat is close to the second fixing seat, so that the structural compactness of the whole mechanism is effectively improved.

Drawings

Fig. 1 is a schematic structural view of the improved multifunctional casting and tamping leveling vibration system.

Fig. 2 is a schematic side view of a material driving mechanism in the improved multifunctional pouring, tamping and leveling vibration system.

Fig. 3 is a schematic perspective view of a material driving mechanism in the improved multifunctional pouring, tamping and leveling vibration system.

Fig. 4 is a schematic perspective view of a vibration mechanism in the multifunctional pouring and tamping leveling vibration system.

Fig. 5 is a schematic top view of a vibration mechanism in the multifunctional casting and tamping leveling vibration system.

Fig. 6 is a schematic diagram of a front view of a vibration mechanism in the multifunctional casting and tamping leveling vibration system.

In the figure, A1, a rack; a2, fixing seat I; a3, a fixing seat II; a3a, a base; a3b, a connecting part; a4, a material driving part; a5, swinging arms; a5a, a positioning cylinder; a6, a material driving shaft; a6a, a rod body; a6b, removing the material sheets; a7, driving wheels; a8, a driven wheel; a9, a material blocking cylinder;

B1, a vibration frame; b1a, a bottom frame; B1B, a cross beam; b1c, a first rod body; b1d, a second rod body; b1e, a rod body III; b1f, rod body IV; b1g, a rod body V; b1h, a rod body six; b2, a vibration seat; b3, vibrating the driving piece; b4, a transmission shaft; b5, an eccentric pendulum;

c1, a roller; and C2, a hopper.

Detailed Description

As shown in FIG. 1, the improved multifunctional pouring, tamping and trowelling vibration system comprises a frame, wherein rollers are arranged at the bottom of the frame, a hopper is arranged at the upper part of the frame, a feed inlet is arranged at the upper part of the hopper, a discharge outlet is arranged at the lower part of the hopper, the discharge outlet is close to the front part of the frame, a vibration mechanism is arranged at the rear part of the frame, and a material driving mechanism is arranged between the vibration mechanism and the discharge outlet of the hopper.

As shown in fig. 2 and 3, the material driving mechanism comprises a first fixing seat A2, a second fixing seat A3, a material driving member A4, a swing arm A5 and a material driving shaft A6, wherein the first fixing seat A2 and the second fixing seat A3 are fixedly connected to a frame A1, the material driving member A4 is fixedly connected to the first fixing seat A2, the inner end of the swing arm A5 is hinged to the material driving shaft A6, the material driving shaft A6 is axially and fixedly connected to the outer end of the swing arm A5, a transmission structure is arranged between the material driving member A4 and the material driving shaft A6, and the material driving member A4 can drive the material driving shaft A6 to rotate through the transmission structure. The material driving shaft A6 comprises a rod body A6a and a material driving sheet A6b, the rod body A6a is in a round rod shape, and the material driving sheet A6b spirally protrudes out of the side part of the rod body A6a

The material driving part A4 is a motor, and the motor is fixedly connected to the first fixing seat A2.

The second fixing seat A3 comprises a base A3a and a connecting part A3b which is positioned on the upper portion of the base A3a and is in a cylindrical shape, the base A3a is fixedly connected to the frame A1 through a fastener, the inner end of the swing arm A5 is hinged to the outer side of the connecting part A3b, and the rotating shaft of the motor is positioned at the connecting part A3 b.

And a bearing is arranged between the motor rotating shaft and the connecting part A3 b.

The outer end of the swing arm A5 is provided with a cylindrical positioning cylinder A5a, and the end part of the material driving shaft A6 is axially and fixedly connected in the positioning cylinder A5 a.

The automatic feeding device also comprises a cylindrical blocking cylinder A9, wherein the outer end of the blocking cylinder A9 is axially fixedly connected with the positioning cylinder A5a, and the inner end of the blocking cylinder A9 is sleeved at the end part of the material driving shaft A6 and is in tight fit connection with the end part of the material driving shaft A6.

A bearing is arranged between the end part of the material driving shaft A6 and the positioning cylinder A5 a.

The rotary shaft of the motor is fixedly connected with a driving wheel A7, the end part of the material driving shaft A6 is fixedly connected with a driven wheel A8, and the driving wheel A7 is connected with the driven wheel A8.

The driving wheel and the driven wheel are both chain wheels, and are connected through a transmission chain.

The driving wheel and the driven wheel are belt wheels and are connected through a transmission belt.

The first fixing seat A2, the second fixing seat A3, the material driving piece A4 and the swing arm A5 form a driving unit, the number of the driving units is two, and the two driving units are respectively positioned at two ends of the material driving shaft A6.

The material driving mechanism is creatively fixed on the frame through the first fixing seat, and the material driving part is firmly fixed on the frame. The inner end of the swing arm is stably hinged on the frame through the second fixing seat.

When the construction operation of driving the material is carried out, the driving piece drives the driving shaft to rotate through the transmission structure, and the rotating driving shaft smoothes the concrete raw material on the upper part of the forming die.

Meanwhile, as the inner ends of the swing arms are hinged to the two rows of the fixing base, the material driving shaft can swing in a proper small amplitude when in material driving operation, and therefore the material driving performance of the material driving shaft is further improved.

As shown in fig. 4, 5 and 6, the vibration mechanism comprises a vibration frame B1, a vibration seat B2, a vibration driving member B3 and a transmission shaft B4, wherein the vibration frame B1 is in a strip shape, the vibration seat B2 is uniformly distributed along the length direction of the vibration frame B1, the transmission shaft 4 is connected with the vibration driving member B3, the vibration driving member B3 can drive the transmission shaft B4 to rotate, the transmission shaft B4 is axially fixedly connected with the vibration seat B2, and the transmission shaft B4 is fixedly connected with an eccentric pendulum B5.

The vibration frame B1 comprises a bottom frame B1a, a cross beam B1B and supporting rods, wherein the bottom frame B1a is square, the cross beam B1B is positioned on the upper portion of the bottom frame B1a, the number of the supporting rods is a plurality of, and two ends of the supporting rods are fixedly connected to the cross beam B1B and the bottom frame B1a respectively.

The beam B1B is arranged in parallel with the bottom frame B1a, the beam B1B is positioned at the center of the bottom frame B1a, and support rods are arranged at the left side and the right side of the beam B1B.

The support rod comprises a first rod body B1c and a second rod body B1d, two ends of the first rod body B1c and the second rod body B1d are fixedly connected to a cross beam B1B and a bottom frame B1a, and the upper ends of the first rod body B1c and the second rod body B1d are intersected and an included angle between the two is 60-120 degrees.

The left side and the right side of the beam B1B are respectively provided with a support rod which is symmetrically arranged, the two groups of support rods form a support unit, the number of the support units is a plurality, and the support units are uniformly distributed along the length direction of the beam B1B.

The end part of the bottom frame B1a is also provided with a rod body three B1e, the rod body three B1e is vertically arranged with the bottom frame B1a, the lower end of the rod body three B1e is fixedly connected with the bottom frame B1a, and the upper end of the rod body three B1e is fixedly connected with the cross beam B1B.

The two sides of the rod body three B1e are provided with a rod body four B1f and a rod body five B1g, the upper ends of the rod body four B1f and the rod body five B1g are fixedly connected to the cross beam B1B, the lower end of the rod body four B1f is fixedly connected to the edge of the bottom frame B1a, and the lower end of the rod body five B1g is fixedly connected to the other edge of the bottom frame B1 a.

The rod body four B1f and the rod body five B1g are symmetrically arranged by taking the rod body three B1e as a reference.

The upper part of the bottom frame B1a is fixedly connected with a rod-shaped rod body six B1h, and the lower end of the vibration seat B2 is fixedly connected to the rod body six B1 h.

The upper end of the vibration seat B2 is sleeved on the transmission shaft B4, and a bearing is arranged between the vibration seat B2 and the transmission shaft B4.

The eccentric pendulum B5 is disc-shaped, and the vertical edge of the eccentric pendulum is fixedly connected to the transmission shaft B4.

The transmission shaft is provided with a plurality of eccentric pendulums which are uniformly distributed along the axial direction of the transmission shaft.

All eccentric pendulums are driven to rotate by the same vibration driving piece, and the non-center positions of the eccentric pendulums are connected to the transmission shaft. Therefore, the eccentric pendulum bob can drive the vibration frame to vibrate, so that the vibration tamping is realized on the concrete raw materials on the forming die.

Claims (8)

1. An improved multifunctional pouring, tamping and leveling vibration system comprises a frame, and is characterized in that a roller is arranged at the bottom of the frame, a hopper is arranged at the upper part of the frame, a feed inlet is arranged at the upper part of the hopper, a discharge hole is arranged at the lower part of the hopper and is close to the front part of the frame, a vibration mechanism is arranged at the rear part of the frame, a material driving mechanism is further arranged between the vibration mechanism and the discharge hole of the hopper, the material driving mechanism comprises a first fixing seat, a second fixing seat, a material driving piece, a swing arm and a material driving shaft, the first fixing seat and the second fixing seat are fixedly connected to the frame, the material driving piece is fixedly connected to the first fixing seat, the material driving shaft is axially fixedly connected to the outer end of the swing arm, a transmission structure is arranged between the material driving piece and the material driving shaft, the material driving piece can drive the material driving shaft to rotate through the transmission structure, the second fixing seat comprises a base and a connecting part which is in a cylindrical shape and is arranged at the upper part of the base, the base is fixedly connected to the frame through a fastener, the inner end of the swing arm is hinged to the outer side of the connecting part, the inner end of the swing arm is hinged to the second fixing seat so that the material driving shaft can swing in a proper small amplitude when in material driving operation, the vibration mechanism comprises a vibration frame, a vibration seat, vibration driving parts and a transmission shaft, the vibration frame is in a strip shape, the vibration seat is uniformly distributed along the length direction of the vibration frame, the transmission shaft is connected with the vibration driving parts and can drive the transmission shaft to rotate, the transmission shaft is axially fixedly connected to the vibration seat, the vibration frame comprises a bottom frame, a cross beam and a supporting rod, the end part of the bottom frame is further provided with a rod body III, the lower end of the rod body III is vertically arranged with the bottom frame and fixedly connected with the bottom frame, the upper end of the rod body III is fixedly connected with the cross beam, two sides of the rod body III are provided with a rod body IV and a rod body V, the upper ends of the rod body IV and the rod body V are fixedly connected to the cross beam, the lower end of the rod body IV is fixedly connected to the edge of the bottom frame, the lower end of the rod body V is fixedly connected to the other edge of the bottom frame, the rod body IV and the rod body V are symmetrically arranged by taking the rod body III as a reference, the rod body VI which is in a rod shape is fixedly connected to the upper portion of the bottom frame, the lower end of the vibration seat is fixedly connected to the rod body VI, the upper end of the vibration seat is sleeved on the transmission shaft, a bearing is arranged between the vibration seat and the transmission shaft, and the eccentric pendulum is fixedly connected to the transmission shaft.

2. The improved multi-functional casting, tamping and vibrating system of claim 1, wherein the material driving member is a motor, and the motor is fixedly connected to the first fixing seat.

3. The improved multi-purpose casting trowelling vibration system of claim 2 wherein said motor shaft is positioned at said connection.

4. The improved multifunctional pouring, tamping and trowelling vibration system of claim 3, wherein the outer end of the swing arm is provided with a cylindrical positioning cylinder, and the end part of the material driving shaft is axially fixedly connected in the positioning cylinder.

5. The improved multifunctional pouring, tamping and vibrating system according to claim 1, wherein the bottom frame is square, the cross beam is located at the upper part of the bottom frame, the number of the support rods is several, and two ends of the support rods are fixedly connected to the cross beam and the bottom frame respectively.

6. The improved multi-purpose casting, tamping and leveling vibration system as recited in claim 5, wherein the cross member is disposed parallel to the bottom frame and centrally located with respect to the bottom frame, and wherein the cross member has support bars on both left and right sides thereof.

7. The improved multifunctional pouring, tamping and vibrating system according to claim 6, wherein the support rod comprises a first rod body and a second rod body, both ends of the first rod body and the second rod body are fixedly connected to the cross beam and the bottom frame, and the upper ends of the first rod body and the second rod body are intersected and an included angle between the upper ends is 60-120 degrees.

8. The improved multifunctional pouring, tamping and trowelling vibration system of claim 7, wherein a set of support bars are symmetrically arranged at the left side and the right side of the cross beam, the two sets of support bars form a plurality of support units, and the support units are uniformly distributed along the length direction of the cross beam.