CN112832533A

CN112832533A - Concrete placement is with device that vibrates

Info

Publication number: CN112832533A
Application number: CN202110018140.1A
Authority: CN
Inventors: 瞿洪
Original assignee: Hangzhou Panling Machinery Technology Co ltd
Current assignee: Hangzhou Panling Machinery Technology Co ltd
Priority date: 2021-01-07
Filing date: 2021-01-07
Publication date: 2021-05-25

Abstract

The invention discloses a vibrating device for concrete pouring, which comprises a lower supporting plate, wherein the lower supporting plate is provided with two bilaterally symmetrical grooves, supporting blocks are fixedly and symmetrically arranged at the left side and the right side of the lower supporting plate, a lifting mechanism comprises an upper motor fixedly arranged on the upper end surface of the supporting block, the supporting block is provided with a vertical groove, the output end of the upper motor penetrates through the upper side wall of the vertical groove to be led into the vertical groove, the output end of the upper motor is fixedly provided with a spiral shaft, the vibrating mechanism can be vertically inserted into concrete, the problem that the concrete cannot be accurately and vertically inserted in the manual use process is effectively solved, a pit left in the insertion process can be filled and leveled to prevent air from entering in the extraction process, the lifting mechanism can realize the operation method of 'fast insertion and slow extraction', the manual operation process is reduced, and the requirement on the proficiency of a user is lowered, the time and the labor are saved, the efficiency is improved, and the reduction of the working time is undoubtedly affirmed to the whole construction team on the premise of ensuring the efficiency in the construction industry.

Description

Concrete placement is with device that vibrates

Technical Field

The invention belongs to the field of buildings, and particularly relates to a vibrating device for concrete pouring.

Background

With the progress of the development era of the society, buildings and roads are more and more constructed, the concrete vibrating operation becomes indispensable work, and if the concrete vibrating operation is not good, the concrete structure can be clamped due to uneven vibration, such as surface layer conveying, defect, exposed tendon or crack. The concrete is not compact, so that the section of the member is weakened, and the bearing capacity of the concrete member is reduced; in addition, slight cavity and crack, inside corrosion reinforcing bar is invaded very easily to outside moisture and gas that are, lead to the structure to destroy early, the vibration is mostly used the tamper on the market at present, and when the tamper used, must accomplish "insert slowly and pull out" soon, and the manual work is wanted to realize "insert slowly and pull out" and is very high and waste time and energy to technical requirement, and will have air admission a little carelessly when pulling out, consequently, wait to design one kind can realize automatically that "insert slowly and pull out" can also prevent to have the device of gaseous entering concrete when pulling out.

Disclosure of Invention

The invention provides a device which can automatically realize fast insertion and slow pulling and can prevent gas from entering concrete during pulling out, aiming at overcoming the defects of the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme: a vibrating device for concrete pouring comprises a lower supporting plate, wherein the lower supporting plate is provided with two bilaterally symmetrical grooves, and supporting blocks are fixedly and symmetrically arranged on the left side and the right side of the lower supporting plate;

the two vibrating mechanisms are respectively arranged in the grooves and are used for vibrating the concrete to remove air bubbles in the concrete, and the concrete is combined compactly;

two elevating system, two elevating system symmetry sets up the left and right sides of backup pad down, elevating system is used for controlling the lift of mechanism of vibrating, can realize pulling out slowly the quick plug of mechanism of vibrating.

Preferably, each supporting block is provided with a supporting block groove, two rollers which are symmetrical front and back are rotatably arranged between the left side wall and the right side wall of the supporting block groove on the left side, each roller is fixedly sleeved with a roller shaft, the upper end face of the lower supporting plate is fixedly provided with a lower rubber block which is circular, and two sliding grooves which are symmetrical left and right are formed in one side, close to each other, of each supporting block.

Preferably, the left vibrating mechanism comprises an upper supporting plate sliding between two supporting blocks, the upper supporting plate is provided with two bilaterally symmetrical vibrating block chutes, each upper supporting plate is provided with two bilaterally symmetrical annular chutes, the annular chutes are communicated with the vibrating block chutes, each annular chute is provided with a short slide block in a sliding manner, the vibrating block chutes are internally provided with vibrating blocks in a sliding manner, the annular chutes are internally provided with short slide blocks in a sliding manner, the short slide blocks are sleeved on the vibrating blocks, four short slide block springs are arranged between the outer circumferential side wall of each short slide block and the side wall of the annular chute, the four short slide block springs are uniformly arranged along the circumferential direction of the short slide blocks of the annular chutes, the vibrating blocks extend downwards through the chutes, the vibrating blocks are provided with motor grooves, and the motor grooves are internally provided with motors, the left end and the right end of the motor are fixedly provided with motor connecting rods, the motor connecting rods are fixedly connected with the left side wall and the right side wall of the motor groove, the output end of the motor is fixedly connected with a shaft, the outer circumferential side surface of the shaft is fixedly sleeved with an annular fixed block, the left side surface of the annular fixed block is fixedly provided with a connecting block, the side surface of the connecting block is fixedly provided with an eccentric block, the left side and the right side of the outer circumferential side wall of the vibrating block are symmetrically provided with teeth, the left side wall and the right side wall of the groove are respectively provided with a rack in a sliding manner, each rack is respectively meshed with a corresponding gear, an annular sliding block is arranged in the motor groove in a sliding manner, the vibrating block is provided with two vibrating block grooves which are bilaterally symmetrical, each vibrating block groove is provided with a fixed plate in a, the gear shaft is sleeved with a gear meshed with the teeth, one end, close to each other, of each of the two fixing plates is fixedly connected with the annular slider, and two annular slider springs which are bilaterally symmetrical are fixedly arranged between the lower end face of the annular slider and the lower side wall of the motor groove.

Preferably, the lifting mechanism comprises two upper motors fixedly arranged on the upper end surfaces of the two supporting blocks, each supporting block is provided with a vertical groove, the output end of each upper motor penetrates through the upper side wall of each vertical groove and leads to the corresponding vertical groove, the output end of each upper motor is fixedly provided with a screw shaft, the lower end surface of each screw shaft is rotatably connected with the lower end surface of each vertical groove, and each screw shaft is provided with a spiral groove.

Preferably, the lifting mechanism further comprises slider grooves symmetrically formed on the left side and the right side of the upper support plate, sliders are arranged in the slider grooves in a sliding manner, the sliders slide in the sliding grooves, the sliders are abutted against the spiral grooves, a slider spring is fixedly arranged between each slider and the groove bottom of each slider groove, a limiting groove is formed in the lower end surface of each slider, two bilaterally symmetrical limiting block spring grooves are formed in the upper support plate, two bilaterally symmetrical rotating rod sliding grooves are formed in the upper support plate, the rotating rod sliding grooves are communicated with the limiting block spring grooves, a limiting block is arranged in each limiting block spring groove in a sliding manner, the upper end surface of each limiting block is an inclined surface, a limiting block spring is fixedly arranged between the lower end surface of each limiting block and the groove bottom of each limiting block spring groove, a left fixing block is fixedly arranged on one side, close, the left rotating shaft fixing block is provided with a left rotating shaft fixing block groove, a left rotating shaft is fixedly arranged in the left rotating shaft fixing block groove, the left rotating shaft sleeve is provided with a rotating rod, a rotating rod shaft is rotatably arranged between the front side wall and the rear side wall of the rotating rod chute, the rotating rod is provided with a rotating rod shaft sliding groove, the rotating rod shaft slides in the rotating rod shaft sliding groove, two rotating rod shaft springs are fixedly arranged between the left side wall and the right side wall of the rotating rod shaft chute and the left side wall and the right side wall of the rotating rod shaft chute, the upper supporting plate is provided with two bilaterally symmetrical fixed rod sliding grooves which are communicated with the rotating rod sliding groove, a fixed rod is slidably arranged in the fixed rod chute, the lower end surface of the fixed rod is fixedly connected with the upper end surface of the lower supporting plate, the lower end face of the upper supporting plate is fixedly provided with an upper rubber block abutted against the lower rubber block.

In summary, the invention has the following advantages:

1. the vibrating mechanism can be vertically inserted into the concrete, the problem that the concrete cannot be accurately vertically inserted in manual use is effectively solved, and a pit left in insertion can be filled and leveled to prevent air from entering in the process of pulling out.

2. The lifting mechanism can realize the operation method of 'fast inserting and slow pulling', the manual operation process is reduced, the requirement on the proficiency of a user is reduced, time and labor are saved, the efficiency is improved, and the reduction of the working time on the premise of ensuring the efficiency in the construction industry is undoubtedly affirmed by the whole construction team.

Drawings

Fig. 1 is a sectional view of a concrete pouring vibrator according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view of a portion of the structure of FIG. 1 taken along line A-A;

FIG. 3 is an enlarged view of a portion of FIG. 1 at I;

FIG. 4 is an enlarged view of a portion of FIG. 1 at II;

FIG. 5 is an enlarged view of a portion of FIG. 3 at III;

fig. 6 is a top view of the present invention.

In the figure, the support block 10; a support block groove 11; a roller 12; a roller shaft 13; a lower support plate 14; a fixed plate 15; a rack 16; a gear shaft 17; a gear 18; a vibrating block 19; an annular slider spring 21; a vibrating block groove 22; an annular slider 23; a vertical block 24; a shaft 25; a groove 27; the teeth 28; a motor 29; a vibrating block chute 30; a lower rubber block 31; an upper rubber block 32; a slider 33; a chute 34; a slider spring 35; a limiting groove 36; an upper support plate 37; a fixing rod 38; a rotating rod chute 39; a fixed rod chute 40; the rotating rod 41; a rotating shaft 42; a left rotating shaft 43; a left rotation axis fixing block groove 44; a left rotating shaft fixing block 45; a stop block 46; stopper springs 47; a stopper spring groove 48; an annular fixing block 49; an eccentric mass 50; a connecting block 51; the slider slots 52; an upper motor 53; a short slider 54; a short slider spring 55; an annular chute 56; a motor connecting rod 57; a screw shaft 58; a spiral groove 59; a vertical slot 60; a motor slot 61; a rotating rod shaft chute 63; the lever shaft spring 64 is rotated.

Detailed Description

As shown in fig. 1, the vibrating device for concrete pouring comprises a lower support plate 14, wherein the lower support plate 14 is provided with two bilaterally symmetrical grooves 27, and support blocks 10 are fixedly and symmetrically arranged at the left side and the right side of the lower support plate 14;

the two vibrating mechanisms A01 and A01 are respectively arranged in the grooves 27, and the vibrating mechanism A01 is used for vibrating the concrete to remove air bubbles in the concrete, so that the concrete is combined compactly;

two elevating system A02, two elevating system A02 symmetry set up the left and right sides in lower supporting plate 14, and elevating system A02 is used for controlling the lift of tamping mechanism A01, can realize inserting fast of tamping mechanism A01 and pull slowly.

Referring to fig. 1 and 6, each support block 10 is provided with a support block groove 11, two rollers 12 which are symmetrical front and back are rotatably arranged between the left side wall and the right side wall of the left support block groove 11, each roller 12 is fixedly sleeved with a roller shaft 13, the upper end surface of the lower support plate 14 is fixedly provided with a lower rubber block 31, the lower rubber block 31 is annular, and two sliding grooves 34 which are symmetrical left and right are formed in the side, close to each other, of the two support blocks 10.

Referring to fig. 1-2 and 4-5, the left vibrating mechanism a01 includes an upper supporting plate 37 sliding between two supporting blocks 10, the upper supporting plate 37 is provided with two bilaterally symmetrical vibrating block chutes 30, each upper supporting plate 37 is provided with two bilaterally symmetrical annular chutes 56, the annular chutes 56 are communicated with the vibrating block chutes 30, each annular chute 56 is provided with a short slide block 54, the vibrating block chute 30 is provided with a vibrating block 19, the annular chute 56 is provided with a short slide block 54, the short slide block 54 is sleeved on the vibrating block 19, four short slide block springs 55 are arranged between the outer circumferential side wall of the short slide block 54 and the side wall of the annular chute 56, the four short slide block springs 55 are uniformly arranged along the circumferential direction of the short slide block 54 of the annular chute 56, the vibrating block 19 extends downwards through the slot 27, the vibrating block 19 is provided with a motor slot 61, the motor 29 is arranged in the motor slot 61, a motor connecting rod 57 is fixedly arranged at the left end and the right end of the motor 29, the motor connecting rod 57 is fixedly connected with the left side wall and the right side wall of the motor groove 61, the output end of the motor 29 is fixedly connected with the shaft 25, the outer circumferential side surface of the shaft 25 is fixedly sleeved with the annular fixed block 49, the left side surface of the annular fixed block 49 is fixedly provided with the connecting block 51, the side surface of the connecting block 51 is fixedly provided with the eccentric block 50, the left side and the right side of the outer circumferential side wall of the vibrating block 19 are symmetrically provided with teeth 28, the left side wall and the right side wall of the groove 27 are respectively provided with the racks 16 in a sliding manner, each rack 16 is respectively engaged with the corresponding gear 18, the motor groove 61 is provided with the annular slide block 23 in a sliding manner, the vibrating block 19 is provided with two vibrating block grooves 22 which are bilaterally symmetrical, the, the gear shaft 17 is sleeved with a gear 18 meshed with the teeth 28, one ends of the two fixing plates 15 close to each other are fixedly connected with an annular slider 23, and two annular slider springs 21 which are bilaterally symmetrical are fixedly arranged between the lower end face of the annular slider 23 and the lower side wall of the motor groove 61.

Referring to fig. 1 and 3, the lifting mechanism a02 includes two upper motors 53 fixedly disposed on the upper end surfaces of the two support blocks 10, each support block 10 is provided with a vertical slot 60, the output end of the upper motor 53 penetrates through the upper side wall of the vertical slot 60 and leads to the vertical slot 60, the output end of the upper motor 53 is fixedly provided with a screw shaft 58, the lower end surface of the screw shaft 58 is rotatably connected with the lower end surface of the vertical slot 60, and the screw shaft 58 is provided with a spiral slot 59.

Referring to fig. 1 and 3, the lifting mechanism a02 further includes slider grooves 52 symmetrically formed on the left and right sides of the upper support plate 37, a slider 33 slidably disposed in the slider grooves 52, the slider 33 slidably disposed in the sliding groove 34, the slider 33 abutting against the spiral groove 59, a slider spring 35 fixedly disposed between each slider 33 and the bottom of each slider groove 52, a limiting groove 36 disposed on the lower end surface of each slider 33, two bilaterally symmetric limiting block spring grooves 48 disposed on the upper support plate 37, two bilaterally symmetric rotating rod sliding grooves 39 disposed on the upper support plate 37, the rotating rod sliding grooves 39 communicating with the limiting block spring grooves 48, a limiting block 46 slidably disposed in each limiting block spring groove 48, an upper end surface of the limiting block 46 being an inclined surface, a limiting block spring 47 fixedly disposed between the lower end surface of the limiting block 46 and the bottom of the limiting block spring groove 48, a left rotating shaft fixing block 45 fixedly disposed on the, a left rotating shaft fixing block groove 44 is formed in the left rotating shaft fixing block 45, a left rotating shaft 43 is fixedly arranged in the left rotating shaft fixing block groove 44, a rotating rod 41 is sleeved on the left rotating shaft 43, a rotating rod shaft 42 is rotatably arranged between the front side wall and the rear side wall of the rotating rod chute 39, a rotating rod shaft chute 63 is formed in the rotating rod 41, the rotating rod shaft 42 slides in the rotating rod shaft chute 63, two rotating rod shaft springs 64 are fixedly arranged between the left side wall and the right side wall of the rotating rod shaft chute 42 and the left side wall and the right side wall of the rotating rod shaft chute 63, two bilaterally symmetrical fixing rod chutes 40 are formed in the upper supporting plate 37, the fixing rod chute 40 is communicated with the rotating rod chute 39, a fixing rod 38 is slidably arranged in the fixing rod chute 40, the lower end face of the fixing rod 38 is fixedly connected with the upper.

The working principle of the vibrating device for concrete pouring provided by the embodiment of the invention is as follows:

when the concrete vibrator is used, the upper motor 53 is started, the upper motor 53 rotates to drive the upper supporting plate 37 to move upwards through the sliding block 33, when the upper supporting plate 37 moves upwards for a certain distance, the upper motor 53 is closed and the supporting block 10 is pushed to move forwards, the supporting block 10 drives the roller shaft 13 to roll on the ground through the roller 12, when the vibrating block 19 is positioned right above concrete, the upper motor 53 is continuously started, the upper motor 53 drives the upper supporting plate 37 to move upwards through the sliding block 33, taking the left side as an example, as the diameter of the spiral shaft 58 is larger than that of the spiral groove 59, when the sliding block 33 slides the outer circumferential surface of the spiral shaft 58 from the spiral groove 59, the sliding block 33 slides rightwards, so that the sliding block spring 35 is compressed, the sliding block 33 drives the limiting groove 36 to slide rightwards, when the limiting groove 36 is positioned right above the limiting block 46, the limiting block spring 47 releases the elastic force to eject the limiting, the limiting block 46 moves upward to drive the left rotating shaft fixing block 45 to move upward, the left rotating shaft fixing block 45 drives the left rotating shaft 43 to move upward, the left rotating shaft fixing block 45 drives the rotating rod 41 to rotate by taking the rotating rod shaft 42 as a rotating center, the rotating rod 41 rotates and compresses the left rotating rod shaft spring 64 so as to stretch the right rotating rod shaft spring 64, when the slider 33 slides out of the spiral groove 59, the limit of the spiral groove 59 to the upper direction and the lower direction is lost, so that the upper supporting plate 37 can move downward rapidly under the action of gravity, the upper supporting plate 37 drives the upper rubber block 32 to move downward to abut against the lower rubber block 31 for buffering, when the rotating rod 41 abuts against the fixing rod 38, the right end of the rotating rod 41 can be jacked up, the rotating rod 41 rotates by taking the rotating rod shaft 42 as a rotating center, so that the left end of the rotating rod 41 moves downward, the left end of the rotating rod 41 drives the left rotating shaft fixing block 45 to move downwards through the left rotating shaft 43, the left rotating shaft fixing block 45 drives the limiting block 46 to move downwards so as to compress the limiting block spring 47, the limiting block 46 moves downwards to slide out of the limiting groove 36, at the moment, the sliding block 33 loses the limiting of the limiting block 46 to the left and right direction, so that the sliding block spring 35 releases elasticity to push the sliding block 33 out to continue to abut against the spiral groove 59, the upper supporting plate 37 drives the vibrating block 19 to move downwards through the short sliding block 54, the vibrating block 19 drives the motor groove 61 to move downwards through the motor connecting rod 57, the motor groove 61 drives the annular fixing block 49, the connecting block 51 and the eccentric block 50 to move downwards through the shaft 25, the vibrating block 19 drives the fixing plate 15 to move downwards through the annular sliding block 23, when the vibrating block 19 is inserted into concrete, the motor 29 is started, and the motor 29, the shaft 25 drives the eccentric block 50 to rotate by taking the shaft 25 as a rotation center through the connecting block 51, when the eccentric block 50 rotates, the shaft 25 drives the shaft 25 to do eccentric motion through the connecting block 51 and the annular fixing block 49 due to inertia, the shaft 25 drives the vibrating block 19 to do eccentric motion through the motor 29 and the motor connecting rod 57, so that the short slider spring 55 is compressed and stretched through the short slider 54, the vibrating block 19 vibrates the surrounding concrete to remove air in the concrete, when the treatment of the part of concrete is finished, the upper motor 53 is started to slowly rotate the upper motor 53, the upper supporting plate 37 is slowly driven to move upwards through the slider 33, the upper supporting plate 37 drives the vibrating block 19 to slowly pull out through the short slider 54, so that 'fast inserting and slow pulling' is realized, when the vibrating block 19 moves upwards, the gear 18 is driven to rotate through the teeth 28, the gear 18 drives the rack 16 to move downwards, the rack 16 drives the fixing plate 15 to move downwards, so that the annular slide block 23 is driven to move downwards to compress the annular slide block spring 21, soil near the vibrating block 19 is squeezed into a hole reserved when the vibrating block 19 is pulled out, air entering is further reduced, and concrete cannot flow into the motor groove 61 from the vibrating block groove 22 due to the length width of the annular slide block 23 and the length of the vibrating block groove 22.

The above embodiments are only preferred embodiments of the present invention, and are not intended to limit the technical solutions of the present invention, so long as the technical solutions can be realized on the basis of the above embodiments without creative efforts, which should be regarded as falling within the protection scope of the patent of the present invention.

Claims

1. The utility model provides a concrete placement is with device that vibrates, includes bottom suspension fagging (14), its characterized in that: the lower supporting plate (14) is provided with two bilaterally symmetrical grooves (27), and the left side and the right side of the lower supporting plate (14) are fixedly and symmetrically provided with supporting blocks (10);

the two vibrating mechanisms (A01) are respectively arranged in the groove (27), and the vibrating mechanism (A01) is used for vibrating the concrete to remove air bubbles in the concrete, so that the concrete is combined compactly;

two elevating system (A02), two elevating system (A02) symmetry sets up the left and right sides of lower support plate (14), elevating system (A02) are used for controlling the lift of tamping mechanism (A01), can realize inserting slowly and drawing fast vibrating mechanism (A01).

2. A concrete placement vibrating device according to claim 1, wherein: every supporting shoe (10) has been seted up supporting shoe groove (11), and the left side rotate between the lateral wall about supporting shoe groove (11) and be provided with two gyro wheels (12) of longitudinal symmetry, every fixed cover is equipped with roller shaft (13) on gyro wheel (12), the fixed rubber block (31) down that is provided with of up end of lower backup pad (14), rubber block (31) are the ring shape down, two spout (34) of two longitudinal symmetries are seted up to one side that supporting shoe (10) are close to each other.

3. A concrete placement vibrating device according to claim 1, wherein: the left vibrating mechanism (A01) comprises an upper supporting plate (37) which slides between two supporting blocks (10), the upper supporting plate (37) is provided with two bilaterally symmetrical vibrating block sliding grooves (30), each upper supporting plate (37) is provided with two bilaterally symmetrical annular sliding grooves (56), the annular sliding grooves (56) are communicated with the vibrating block sliding grooves (30), each annular sliding groove (56) is internally provided with a short sliding block (54) in a sliding manner, the vibrating block sliding grooves (30) are internally provided with vibrating blocks (19) in a sliding manner, the annular sliding grooves (56) are internally provided with short sliding blocks (54) in a sliding manner, the short sliding blocks (54) are sleeved on the vibrating blocks (19), four short sliding block springs (55) are arranged between the outer circumferential side wall of the short sliding blocks (54) and the side wall of the annular sliding grooves (56), and the four short sliding block springs (55) are uniformly arranged along the circumferential direction of the short sliding blocks (54) of the annular sliding grooves (56), the utility model discloses a vibrating machine, including vibrating block (19), groove (27), vibrating block (19) have seted up motor groove (61), be provided with motor (29) in motor groove (61), both ends are fixed to be provided with motor connecting rod (57) about motor (29), motor connecting rod (57) with the left and right sides wall fixed connection of motor groove (61), the output fixedly connected with axle (25) of motor (29), the outer circumference side fixed cover of axle (25) is equipped with annular fixed block (49), the left side fixed of annular fixed block (49) is provided with connecting block (51), the fixed eccentric block (50) that is provided with in side of connecting block (51), the left and right sides symmetry of the outer circumference lateral wall of vibrating block (19) is provided with tooth (28), it is provided with rack (16) to slide on the left and right lateral wall of groove (27) respectively, every rack (16) meshes with corresponding gear (18) respectively, it is provided with annular slider (23) to slide in motor groove (61), the vibrating block groove (22) of two bilateral symmetry is seted up in vibrating block (19), every it is provided with fixed plate (15) to slide in vibrating block groove (22), the fixed vertical piece (24) that is provided with of up end of fixed plate (15), the leading flank of vertical piece (24) rotates and is provided with gear shaft (17), the cover is equipped with on gear shaft (17) with gear (18) of tooth (28) meshing, two the one end that fixed plate (15) are close to each other with annular slider (23) fixed connection, the lower terminal surface of annular slider (23) with fixed two bilateral symmetry's annular slider spring (21) of being provided with between the lower lateral wall of motor groove (61).

4. A concrete placement vibrating device according to claim 1, wherein: the lifting mechanism (A02) comprises two upper motors (53) fixedly arranged on the upper end surfaces of the two supporting blocks (10), each supporting block (10) is provided with a vertical groove (60), the output end of each upper motor (53) penetrates through the upper side wall of each vertical groove (60) to lead to the corresponding vertical groove (60), the output end of each upper motor (53) is fixedly provided with a spiral shaft (58), the lower end surface of each spiral shaft (58) is rotatably connected with the lower end surface of each vertical groove (60), and each spiral shaft (58) is provided with a spiral groove (59).

5. The concrete placement vibrating device of claim 4, wherein: elevating system (A02) still sets up including the symmetry go up the slider groove (52) of backup pad (37) left and right sides, it is provided with slider (33) to slide in slider groove (52), slider (33) are in slide in spout (34), slider (33) with helicla flute (59) butt, every slider (33) and every fixed slider spring (35) that is provided with between the tank bottom of slider groove (52), every spacing groove (36) have been seted up to the lower terminal surface of slider (33), go up backup pad (37) and seted up two bilateral symmetry's stopper spring groove (48), go up backup pad (37) and seted up two bilateral symmetry's dwang spout (39), dwang spout (39) with stopper spring groove (48) intercommunication, every it is provided with stopper (46) to slide in stopper spring groove (48), the upper end surface of each limiting block (46) is an inclined surface, a limiting block spring (47) is fixedly arranged between the lower end surface of each limiting block (46) and the bottom of each limiting block spring groove (48), a left rotating shaft fixing block (45) is fixedly arranged on one side, close to each other, of each limiting block (46), a left rotating shaft fixing block groove (44) is formed in each left rotating shaft fixing block (45), a left rotating shaft (43) is fixedly arranged in each left rotating shaft fixing block groove (44), a rotating rod (41) is sleeved on each left rotating shaft (43), a rotating rod shaft (42) is rotatably arranged between the front side wall and the rear side wall of each rotating rod sliding groove (39), a rotating rod shaft sliding groove (63) is formed in each rotating rod (41), each rotating rod shaft (42) slides in each rotating rod shaft sliding groove (63), and two rotating rod shaft springs (a) are fixedly arranged between the left side wall and the right side wall of each rotating 64) The utility model discloses a rubber block (31) butt end fixing device, two bilateral symmetry's dead lever spout (40) are seted up to last backup pad (37), dead lever spout (40) with dwang spout (39) intercommunication, it is provided with dead lever (38) to slide in dead lever spout (40), the lower terminal surface of dead lever (38) with the up end fixed connection of lower backup pad (14), the lower terminal surface fixed of going up backup pad (37) be provided with last rubber block (32) of lower rubber block (31) butt.