CN210483076U

CN210483076U - Advanced configuration concrete row that vibrates

Info

Publication number: CN210483076U
Application number: CN201921312585.5U
Authority: CN
Inventors: 王祥国; 徐龙军; 梁景江; 于等文; 张玉才; 杜维松
Original assignee: Heilongjiang Province Water Resources And Hydropower Group Co ltd
Current assignee: Heilongjiang Province Water Resources And Hydropower Group Co ltd
Priority date: 2019-08-12
Filing date: 2019-08-12
Publication date: 2020-05-08
Anticipated expiration: 2029-08-12

Abstract

An advanced configuration concrete vibrating row relates to the field of configuration concrete mechanical equipment. For solving current vibrating rod can not many simultaneous uses, can produce the concrete aggregate if many simultaneous uses and pile up and the phenomenon of layering segregation to use single vibrating rod, its vibration area of coverage is less need constantly replace the plug, the long extravagant manpower and materials of required time of using, and can not adjust the problem of the speed of vibrating. The upper surface one end of frame is equipped with motor and gearbox in proper order, the frame upper surface is equipped with a transmission shaft along the width direction equidistance in proper order, No. two transmission shafts and No. three transmission shafts, the one end of a transmission shaft is passed the gearbox and is connected with the output of motor, the even a plurality of cams that are equipped with on every transmission shaft, the even a plurality of through-holes that are equipped with in the frame, and the axis of every through-hole all corresponds with the axis of the epaxial cam of transmission, be equipped with the unit of vibrating in every through-hole in the frame, and every unit of vibrating and frame sliding connection. The utility model is suitable for a configuration concrete.

Description

Advanced configuration concrete row that vibrates

Technical Field

The utility model relates to a configuration concrete mechanical equipment field, concretely relates to senior configuration concrete row of vibrating.

Background

At present, in order to better remove air bubbles mixed in concrete during the hardening process, a vibrating rod is inserted to remove air in the concrete in a vibrating mode, so that the density of the hardened concrete is improved. However, the existing vibrating rod has a single structure, the vibration coverage area is small, and the position of the vibrating rod needs to be changed continuously, so that the concrete is not uniformly tamped, and air bubbles are easily generated. Moreover, if a plurality of vibrating rods work simultaneously, the phenomenon of layered segregation caused by accumulation of concrete aggregates is generated because of difference of vibration amplitudes of the vibrating rods, only one vibrating rod is used, and therefore the vibrating rods need to be continuously replaced and plugged, the required using time is long, manpower and material resources are wasted, and the vibrating speed cannot be adjusted.

To sum up, current vibrating rod can not many simultaneous use, if many simultaneous use can produce the concrete aggregate pile and the phenomenon of layering segregation to use single vibrating rod, its vibration coverage area is less, need constantly replace the plug, and required time of using is long, extravagant manpower and materials, and can not adjust the speed of vibrating.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve present vibrating rod and can not many simultaneous use, if many simultaneous uses can produce the concrete and gather materials and pile up and the phenomenon of layering segregation to use single vibrating rod, its vibration coverage area is less, need constantly replace the plug, the time of required use is long, extravagant manpower and materials, and can not adjust the problem of the speed of vibrating, and provide a senior configuration concrete row of vibrating.

The utility model relates to an advanced concrete vibrating row, which comprises a motor, a gearbox, a cam, a first transmission shaft, a vibrating unit, a second transmission shaft, a third transmission shaft and a frame;

the automatic stamping machine comprises a rack, a motor, a gearbox, a first transmission shaft, a second transmission shaft, a third transmission shaft, a plurality of through holes, a plurality of cams, a plurality of tamping units and a stamping unit, wherein the motor and the gearbox are sequentially arranged at one end of the upper surface of the rack, the three transmission shaft supports are equidistantly arranged at the other end of the upper surface of the rack along the width direction, the first transmission shaft, the second transmission shaft and the third transmission shaft are equidistantly arranged on the upper surface of the rack along the width direction, one end of the first transmission shaft and one end of the third transmission shaft are inserted into the gearbox, one end of the first transmission shaft penetrates through the gearbox and is connected with the output end of the motor, the other ends of the first transmission shaft, the second transmission shaft and the third transmission shaft are sequentially connected with the three transmission shaft supports on the upper surface of the rack, the plurality of cams;

the transmission case comprises a first gear, a second gear, a sliding gear, a third gear, a driving gear and a push rod, wherein the driving gear and the third gear are sequentially arranged at one end of a first transmission shaft in the transmission case, the driving gear and the third gear are respectively and fixedly connected with the first transmission shaft through key slots, a sleeve and the sliding gear are sequentially arranged at one end of the second transmission shaft in the transmission case, one end of the sleeve penetrates through a shell of the transmission case and is fixedly connected with one end of the push rod, the other end of the sleeve is fixedly connected with one end face of the sliding gear, the first gear and the second gear are sequentially arranged at one end of the third transmission shaft in the transmission case, and the first gear and the driving gear are respectively meshed with the sliding gear;

furthermore, the vibrating unit comprises springs, a vibrating rod, a top rod and a supporting sheet, one end of the vibrating rod is provided with a cylinder with a cavity at the tip and the other end, the edge of the top end of the vibrating rod is uniformly provided with a plurality of springs, the supporting sheet is arranged inside the vibrating rod, the center of the supporting sheet is fixedly connected with the bottom end of the top rod, the vibrating rod penetrates through a through hole in the rack, the top end of the spring on the vibrating rod is fixedly connected with the top end inside the through hole, and the top end of the top rod is in matched contact with a cam on the transmission shaft;

furthermore, the number of the springs is 2-5;

furthermore, the number of the cams is 4-10;

further, the input voltage of the motor is 220 v;

further, the motor is a stepping motor;

furthermore, the supporting sheet is welded with the bottom of the ejector rod;

furthermore, when the device is used, a rack of the device is erected on a steel bar wall of building cement, a vibrating row is inserted into the concrete, the power supply is connected, the motor is started, the motor drives a transmission shaft to rotate through a single gearbox, a second transmission shaft and a third transmission shaft can be respectively driven to rotate by utilizing the meshing of gears in a gearbox, each transmission shaft drives a cam to rotate, the rotation of the cam pushes an ejector rod to enable the vibrating rod to move downwards, the vibrating rod is quickly reset by utilizing the elasticity of a spring, the cam continuously rotates, and the vibrating rod can do up-and-down reciprocating motion;

when the vibration speed needs to be adjusted, the push rod is pushed, so that the sliding gear in the gearbox is pushed through the sleeve, the end face of the pinion on the sliding gear is meshed and connected with the second gear and the third gear respectively, and the vibration speed can be adjusted.

Compared with the prior art, the utility model following beneficial effect has:

firstly, the utility model overcomes the defects of the prior art, adopts a plurality of cams which are evenly arranged on the transmission shaft, and each cam is arranged on the transmission shaft

The bottom of cam corresponds a unit that vibrates to form the row that vibrates, realized a plurality of vibrating rod one time, same frequency up-and-down reciprocating motion has improved the area of vibrating, the material piles up and the phenomenon of layering segregation when avoiding appearing vibrating.

Two, the utility model discloses a rotational speed of three transmission shafts is controlled to the gearbox to the speed of vibrating of unit has been controlled, thereby has realized adjusting the speed of vibrating.

Thirdly, adopt when the construction a senior configuration concrete row of vibrating, avoid using single vibrating rod, its vibration coverage area is less, need constantly replace the problem of plug, reduce time has saved the manpower to efficiency has been improved.

Drawings

Fig. 1 is a front view of the overall structure of the present invention;

fig. 2 is a plan view of the overall structure of the present invention.

Detailed Description

The first embodiment is as follows: the embodiment is described with reference to fig. 1 and 2, and the advanced configuration concrete vibrating row in the embodiment comprises a motor 1, a gearbox 2, a cam 3, a first transmission shaft 4, a vibrating unit, a second transmission shaft 10, a third transmission shaft 11 and a rack 12;

one end of the upper surface of the frame 12 is sequentially provided with a motor 1 and a gear box 2, the other end of the upper surface of the frame 12 is provided with three transmission shaft supports at equal intervals along the width direction, the upper surface of the frame 12 is sequentially provided with a first transmission shaft 4, a second transmission shaft 10 and a third transmission shaft 11 at equal intervals along the width direction, one ends of a second transmission shaft 10 and a third transmission shaft 11 are inserted into the gear box 2, one end of a first transmission shaft 4 penetrates through the gear box 2, is connected with the output end of the motor 1, the other ends of the first transmission shaft 4, the second transmission shaft 10 and the third transmission shaft 11 are sequentially connected with three transmission shaft brackets on the upper surface of a frame 12, a plurality of cams 3 are uniformly arranged on each transmission shaft, a plurality of through holes are uniformly arranged on the frame 12, the axis of each through hole corresponds to the axis of the cam 3 on the transmission shaft, a vibrating unit is arranged in each through hole on the rack 12, and each vibrating unit is connected with the rack 12 in a sliding manner;

the transmission case 2 comprises a first gear 2-1, a second gear 2-2, a sliding gear 2-3, a third gear 2-4, a driving gear 2-5 and a push rod 9, wherein one end of a first transmission shaft 4 in the transmission case 2 is sequentially provided with the driving gear 2-5 and the third gear 2-4, the driving gear 2-5 and the third gear 2-4 are respectively and fixedly connected with the first transmission shaft 4 through a key slot, one end of a second transmission shaft 10 in the transmission case 2 is sequentially provided with a sleeve and the sliding gear 2-3, one end of the sleeve penetrates through a shell of the transmission case 2 and is fixedly connected with one end of the push rod 9, the other end of the sleeve is fixedly connected with one end face of the sliding gear 2-3, one end of a third transmission shaft in the transmission case 2 is sequentially provided with the first gear 2-1 and the second gear 2-2, the first gear 2-1 and the driving gear 2-5 are respectively meshed with the sliding gear 2-3;

this embodiment, the adoption is even on the transmission shaft is equipped with a plurality of cams, and the bottom of every cam corresponds a unit that vibrates to form the row that vibrates, realized a plurality of vibrating rod one time, same frequency up-and-down reciprocating motion has improved the area of vibrating, and the material is piled up and the phenomenon of layering segregation when avoiding appearing vibrating, and adopts the gearbox to control the rotational speed of three transmission shafts, thereby has controlled the speed of vibrating of the unit that vibrates, thereby has realized adjusting the speed of vibrating.

The second embodiment is as follows: the present embodiment is described with reference to fig. 2, and is further limited to the vibrating row described in the first embodiment, which is an advanced configuration concrete vibrating row described in the present embodiment, the vibrating unit includes a spring 5, a vibrating rod 6, a top rod 7 and a support plate 8, one end of the vibrating rod 6 is provided with a cylinder shape having a cavity at the tip and the other end, a plurality of springs 5 are uniformly arranged at the edge of the top end of the vibrating rod 6, the support plate 8 is arranged inside the vibrating rod 6, the center of the support plate 8 is fixedly connected with the bottom end of the top rod 7, the vibrating rod 6 passes through a through hole on the frame 12, the top end of the spring on the vibrating rod 6 is fixedly connected with the top end inside the through hole, and the top end of the top rod 7 is in matching contact with the cam 3 on the transmission shaft;

in the specific embodiment, the vibrating rod 6 is connected with a through hole in the rack 12 through the spring 5, the motor 1 is started to transmit power to the first transmission shaft 4 through the gearbox 2, the first transmission shaft 4 rotates to drive the cam 3 to rotate, the cam 3 rotates to push the ejector rod 7, the vibrating rod 6 moves downwards, the vibrating rod 6 is quickly reset through the elasticity of the spring 5, the cam 3 continuously rotates, and the vibrating rod 6 can do vertical reciprocating motion;

when the device is used, a rack 12 of the device is erected on a steel bar wall of building cement, a vibrating row is inserted into the concrete, a power supply is connected, a motor 1 is started, the motor 1 drives a first transmission shaft 4 to rotate through a single-piece gearbox 2, a second transmission shaft 10 and a third transmission shaft 11 can be respectively driven to rotate by utilizing gear engagement in the gearbox 2, each transmission shaft drives a cam 3 to rotate, the cam 3 rotates to push an ejector rod 7, a vibrating rod 6 moves downwards, the vibrating rod 6 is quickly reset by utilizing the elasticity of a spring 5, the cam 3 continuously rotates, and the vibrating rod 6 can do vertical reciprocating motion;

when the vibration speed needs to be adjusted, the push rod 9 is pushed, so that the sliding gear 2-3 in the gearbox is pushed through the sleeve, the end face of the pinion on the sliding gear 2-3 is respectively meshed and connected with the second gear 2-2 and the third gear 2-4, and the vibration speed can be adjusted.

The third concrete implementation mode: the present embodiment is described with reference to fig. 2, and is a further limitation of the vibrating row of the second embodiment, and the number of the springs 5 is 2 to 5 in the concrete vibrating row of the first embodiment.

The fourth concrete implementation mode: the present embodiment is described with reference to fig. 2, and is a further limitation of the vibrating row described in the first embodiment, and the number of the cams 3 in the concrete vibrating row arranged at a higher level in the present embodiment is 4 to 10.

The fifth concrete implementation mode: the present embodiment is described with reference to fig. 2, and is a further limitation of the vibrating row described in the first embodiment, and the input voltage 220v of the motor 1 is set for the concrete vibrating row arranged at a higher level in the present embodiment.

The sixth specific implementation mode: the present embodiment is described with reference to fig. 2, and is a further limitation to the vibrating row described in the fifth embodiment, and the motor 1 is a stepping motor in the advanced concrete vibrating row described in the present embodiment.

The seventh embodiment: the present embodiment is described with reference to fig. 2, and is a further limitation to the vibrating row described in the second embodiment, and in the present embodiment, the support plate 8 and the bottom of the top bar 7 are welded.

Principle of operation

Claims

1. The utility model provides a senior configuration concrete row that vibrates which characterized in that: the vibration machine comprises a motor (1), a gearbox (2), a cam (3), a first transmission shaft (4), a vibration unit, a second transmission shaft (10), a third transmission shaft (11) and a rack (12);

one end of the upper surface of a rack (12) is sequentially provided with a motor (1) and a gearbox (2), the other end of the upper surface of the rack (12) is provided with three transmission shaft supports at equal intervals along the width direction, the upper surface of the rack (12) is sequentially provided with a first transmission shaft (4), a second transmission shaft (10) and a third transmission shaft (11) at equal intervals along the width direction, one ends of the second transmission shaft (10) and the third transmission shaft (11) are inserted into the gearbox (2), one end of the first transmission shaft (4) penetrates through the gearbox (2) and is connected with the output end of the motor (1), the other ends of the first transmission shaft (4), the second transmission shaft (10) and the third transmission shaft (11) are sequentially connected with the three transmission shaft supports at the upper surface of the rack (12), each transmission shaft is uniformly provided with a plurality of cams (3), each rack (12) is uniformly provided with a plurality of through holes, and the axis of each through hole corresponds to the axis of each cam, each through hole on the rack (12) is internally provided with a vibrating unit, and each vibrating unit is connected with the rack (12) in a sliding way;

the gearbox (2) comprises a first gear (2-1), a second gear (2-2), a sliding gear (2-3), a third gear (2-4), a driving gear (2-5) and a push rod (9), wherein one end of a first transmission shaft (4) in the gearbox (2) is sequentially provided with the driving gear (2-5) and the third gear (2-4), the driving gear (2-5) and the third gear (2-4) are respectively and fixedly connected with the first transmission shaft (4) through key slots, one end of a second transmission shaft (10) in the gearbox (2) is sequentially provided with a sleeve and the sliding gear (2-3), one end of the sleeve penetrates through a shell of the gearbox (2) and is fixedly connected with one end of the push rod (9), the other end of the sleeve is fixedly connected with one end face of the sliding gear (2-3), one end of a third transmission shaft in the gearbox (2) is sequentially provided with a first gear (2-1) and a second gear (2-2), and the first gear (2-1) and the driving gear (2-5) are respectively meshed with the sliding gear (2-3).

2. The advanced configuration concrete tamper bank of claim 1, wherein: the unit of vibrating include spring (5), vibrating stick (6), ejector pin (7) and backing sheet (8), vibrating stick (6) one end is equipped with the cylinder form that sharp portion other end opening has the cavity, the even a plurality of springs (5) that are equipped with of top edge of vibrating stick (6), the inside of vibrating stick (6) is equipped with backing sheet (8), the center department of backing sheet (8) and the bottom fixed connection of ejector pin (7), vibrating stick (6) pass the through-hole on frame (12), the spring top on vibrating stick (6) and the inside top fixed connection of through-hole, and the top of ejector pin (7) and epaxial cam (3) cooperation contact of transmission.

3. An advanced configuration concrete tamper bank according to claim 2, wherein: the number of the springs (5) is 2-5.

4. An advanced configuration concrete tamper bank according to claim 2, wherein: the supporting sheet (8) is welded with the bottom of the ejector rod (7).

5. The advanced configuration concrete tamper bank of claim 1, wherein: the number of the cams (3) is 4-10.

6. The advanced configuration concrete tamper bank of claim 1, wherein: the input voltage of the motor (1) is 220 v.

7. An advanced configuration concrete tamper bank according to claim 6, wherein: the motor (1) is a stepping motor.