JP2022135817A - Excess casting monitoring device for caisson pile - Google Patents

Abstract

To provide an excess casting monitoring device for a caisson pile which includes a monitoring part and a moving part.SOLUTION: An excess casting monitoring device for a caisson pile includes a monitoring part and a moving part, wherein the monitoring part includes a pedestal 3 including a fixed pedestal fixed to a pile outer frame 1 of a caisson pile, and an excess casting monitor. The moving part includes a ground contact block 51, a chain 52, a first relay gear 53, a second relay gear 54, and a drive gear 55. The excess casting monitor is always kept at a constant height. When the caisson pile reaches a target height, a signal is emitted from the excess casting monitor. After an operator receives the signal, the corresponding casting is stopped, avoiding excess casting of the caisson pile.SELECTED DRAWING: Figure 1

Description

The present invention relates to the field of caisson pile monitoring devices, and more particularly to caisson pile overload monitoring devices.

With the economic development, more and more buildings, bridges and other structures have been constructed. In the construction process, caisson piles are widely used due to their advantages such as low vibration, no compaction and low construction noise. In the construction process of pouring caisson piles, it is necessary to pour concrete into the outer frame of the pile, and when pouring concrete, it is necessary to determine the amount of concrete to be poured. Construction efficiency decreases. If the pouring height is too high, it is necessary to remove the overfilled portion after the concrete hardens, wasting not only man-hours but also excess concrete material. To avoid the occurrence of overfilling, an overfilling monitoring device configured to monitor the pouring height of the concrete must be installed. Most of the conventional monitoring devices for caisson piles are directly hung on the outer frame of the standard pile. and obtain the pouring height by calculating the monitoring data, which is too troublesome. When the monitoring device is hung on the outer frame of the pile by the circumscribing hook, the circumscribing hook needs to have a sufficient height as the outer frame of the pile rises, which takes a long time to assemble.

The problem to be solved by the invention is to adjust the position of the monitoring part according to the rising position of the pile outer frame so as to overcome the defect that the monitoring part in the prior art moves with the pile outer frame and cannot monitor. To provide a caisson pile overload monitoring device that can achieve a good monitoring effect.

In order to achieve the above object, the present invention uses the following technical solutions.

According to the invention,
A caisson pile overload monitoring device is provided that includes a monitoring portion and a moving portion.
The monitoring unit comprises a pedestal including a fixed seat for fixing to the outer frame of the pile mouth pile of the caisson pile, and an overflow monitoring device inserted into the pedestal, and the moving part comprises a ground block, a chain and , a first intermediate gear, a second intermediate gear, and a drive gear, one end of the chain is fixedly connected to the ground block, and the first intermediate gear is rotatably attached to the end of the fixed seat; the second relay gear is rotatably connected inside the base; the drive gear is rotatably connected inside the base; the chain connects the first relay gear, the second relay gear, and the drive It meshes with gears in this order. The overload monitoring device comprises a housing, a motor, a transmission shaft, wings, and a speed measuring unit, the motor is fixed inside the housing, and one end of the transmission shaft is connected to the power output end of the motor. fixed connection, the blade is fixed to the other end of the transmission shaft, the speed measuring part is fixed to the pedestal and connected to the transmission shaft, the outer wall of the housing is provided with a tooth hole row, and the driving gear is , meshed with the dentition row.

In a preferred embodiment of the present invention, the fixed seat is composed of a fixed ring and two or more support arms, the two or more support arms are uniformly provided outside the fixed ring, and the support arms are , a telescopic rod and a fixed block, the fixed end of the support arm is fixed to the outer wall of the fixed ring, the fixed block is fixed to the free end of the support arm, and the bottom of the fixed block is provided with an arc-shaped groove. A fixed ring is fitted to the exterior of the housing, and the first relay gear is rotatably connected to one of the fixed blocks.

In a preferred aspect of the present invention, the speed measuring unit includes a gear ring, a monitoring gear, and a rotation speed detection device, the gear ring is fitted on the drive shaft, and the monitoring gear is the rotation speed detection device. Fixed to the monitoring end and meshed with a gear ring.

In a preferred aspect of the present invention, a fixing nail is provided on the bottom of the ground block, and a through hole through which a final tightening bolt is inserted is provided in the ground block.

In a preferred embodiment of the present invention, the caisson pile overload monitoring device further comprises a reinforcement assembly including two or more reinforcement arms including a support bar, a spring, a wheel seat and a rotating ring, the support bar being attached to the housing. Fixed on both sides of the lower end, a wheel seat is fixed to the end of said support rod via a spring, and two or more rotating wheels are rotatably connected to the wheel seat.

In a preferred aspect of the present invention, the overflow monitoring device further comprises a processor, a warning light, and a pre-activation unit, the processor and pre-activation unit are both disposed on the housing, and the warning light is provided on the housing. Fixed on the upper part of the body, the speed measuring part, the pre-activation part and the warning light are each electrically connected to the processor.

In a preferred embodiment of the present invention, the pre-starting part comprises a tractive force sensor, a connecting rope, a mesh frame, a counterweight block and a flat plate, the tractive force sensor being located inside the housing and a monitoring end of the tractive force sensor. is connected to one end of the connecting rope, the other end of the connecting rope is connected to the mesh frame, the counterweight block is placed on the mesh frame, the flat plate is fixed to the bottom wall of the mesh frame, the traction force sensor is electrically connected to the processor;

In a preferred aspect of the present invention, a fixing rod is fixedly installed on the top of the pedestal, a positioning hole is provided in the housing, and the fixing rod is fitted into the positioning hole.

The invention has the following beneficial effects.
According to the caisson pile overload monitoring device of the present invention, the pile shell rises during the pouring process to keep the overload monitoring device at a constant height and to maintain accurate monitoring of the caisson pile. Along with this, the moving part can correspondingly raise the overflow monitoring device arranged in the monitoring part. When the caisson pile reaches the target height, a signal will be emitted from the overload monitoring device, and after the operator receives the signal, the corresponding pouring will be stopped to avoid the caisson pile from being overfilled. Avoid deviation of monitoring data due to deviation of monitoring position due to movement of pile outer frame.

1 is a structural schematic diagram of a caisson pile overload monitoring device according to the present invention; FIG.

Hereinafter, the technical solution of the present invention will be further described with reference to specific embodiments and drawings.

As shown in FIG. 1, the embodiment provides a caisson pile overload monitoring device comprising a monitoring portion and a moving portion.
The monitoring part comprises a pedestal 3 including a fixed seat for fixing to the pile mouth pile outer frame 1 of the caisson pile, and an overflow monitoring device inserted into the pedestal 3. The moving part comprises a ground block 51, It comprises a chain 52, a first intermediate gear 53, a second intermediate gear 54 and a driving gear 55, one end of the chain 52 is fixedly connected to the ground block, and the first intermediate gear 53 is a fixed seat. , a second intermediate gear 54 is rotatably connected inside the pedestal 3, a drive gear 55 is rotatably connected inside the pedestal 3, and a chain 52 is connected to the first intermediate gear 53, the second intermediate gear 54, and the drive gear 55 in this order. The overload monitoring device includes a housing 41, a motor 42, a transmission shaft 43, wings 44, and a speed measuring unit. The motor 42 is fixed inside the housing 41, and one end of the transmission shaft 43 is , is fixedly connected to the power output end of the motor 42, the blade 44 is fixed to the other end of the transmission shaft 43, the speed measuring unit is fixed to the base and connected to the transmission shaft 43, and is attached to the outer wall of the housing 41. is provided with a tooth hole row 48, and the driving gear 55 is meshed with the tooth hole row 48. As shown in FIG.

Before the pouring work, the monitoring part is hung on the tip of the pile mouth outer frame 1 via the fixing seat, and the grounding block 51 arranged in the moving part is fixed to the ground outside the pile outer frame 1. . By adjusting the height of the monitoring part on the fixed seat, the position of the wing 44 located in the overload monitoring device within the pile shell 1 is the target pouring height of the caisson pile. After that, the concrete pouring operation can be started, and at the same time the motor 42 is activated, and the motor 42 rotates the blade 44 via the transmission shaft 43 . The rotation speed of the transmission shaft 43 is monitored by the speed measuring unit, and when the concrete reaches the target pouring height, the concrete blocks the rotation of the blades 44 and reduces the rotation speed of the transmission shaft 43 . When the speed measuring unit detects a decrease in the number of rotations of the transmission shaft 43, it can know that the concrete has reached the target pouring height and stop pouring the concrete. If the pile outer frame 1 needs to be pulled out at the same time as the pouring work, the pile outer frame 1 is pulled upward, and the moving part starts to operate at the same time. The fixed seat and pedestal 3 move together with the pile shell 1, one end of the chain 52 is fixed to the ground block 51, and the ground block is fixed to the ground, so that when the pile shell 1 raises the pedestal 3 , the chain 52 located in the monitoring part is pulled, and the chain 52 located in the pedestal is pulled up under the support of the first intermediate gear 53 and the second intermediate gear 54. At this time, the chain 52 pulls After the drive gear 55 is rotated, the drive gear 55 is engaged with the tooth hole array 48 on the housing 41, thereby lowering the members such as the motor 42 and the transmission shaft 43 together with the housing 41, thereby forming the pile. The raised height of the outer frame 1 is matched with the lowered height of the overload monitoring device, so that the height of the overload monitoring device can be kept constant, and the wings 44 arranged on the overload monitoring device are fixed. , so as to avoid the monitoring data error due to the rise of the monitoring wing 44 during the rise of the pile outer frame 1 . The monitoring device according to the present embodiment can always maintain the monitoring part at an appropriate height as the pile outer frame 1 rises, and the monitoring effect is not affected by the height of the pile outer frame 1. guaranteed. In addition, the trouble of repeatedly adjusting the height of the overflow monitoring device during the test process is reduced, the accuracy of monitoring is improved, and the difficulty of monitoring operation is reduced.

In one embodiment of the present invention, the fixed seat is composed of a fixed ring 21 and two or more support arms, and the two or more support arms are evenly provided on the outside of the fixed ring 21 to provide support. The arm comprises a telescopic rod 22 and a fixed block 23, the fixed end of the support arm is fixed to the outer wall of the fixed ring 21, the fixed block 23 is fixed to the free end of the support arm, and the bottom of the fixed block 23 is provided with an arcuate groove 24 , the fixed ring 21 is fitted on the outside of the housing 41 , and the first intermediate gear 53 is rotatably connected to one of the fixed blocks 23 . The fixing ring 21 is fitted on the outside of the overload monitoring device, and through the telescopic rod 22, the length of the support arm can be adjusted to accommodate different diameters of the pile outer frame 1, and the telescopic rod 22 can be adjusted to a suitable length. After adjusting the height, the fixing block 23 is fitted to the wall of the pile outer frame 1 so that the pile outer frame 1 is fitted into the arc-shaped groove 24 . By fixing the overload monitoring device to the pile outer frame 1 in this way, when the pile outer frame 1 moves up and down, the pedestal 3 can be moved together with the pile outer frame 1, and cooperates with the moving part. , the overload monitoring device can monitor at a certain height.

In one embodiment of the invention, the speed measuring unit comprises a gear ring 45, a monitoring gear 46 and a rotation speed detector 47, the gear ring 45 being fitted on the drive shaft and the monitoring gear 46 being a rotating It is fixed to the monitoring end of the number detector and meshed with gear ring 45 . The transmission shaft 43 rotates the monitoring gear 46 through the gear ring 45, and when the monitoring gear 46 rotates, its rotation speed, that is, the rotation speed of the transmission shaft 43, can be detected by the rotation speed detection device 47. . Before the height of the caisson pile reaches the target height, the wing 44 can be rotated without hindrance, so the rotation speed of the transmission shaft 43 can be kept relatively stable. When the height of the concrete approaches or reaches the target height, the concrete obstructs the rotation of the blade 44 and reduces the rotation speed of the transmission shaft 43, and the rotation speed sensor detects the reduction in the rotation speed of the transmission shaft 43 is detected, it indicates that the pouring height has reached the target height, and the pouring work can be stopped to realize the function of overfilling monitoring and avoid overfilling.

In one embodiment of the present invention, the bottom of the ground block 51 is provided with a fixing nail 511, and the ground block 51 is provided with a through-hole through which a final tightening bolt 512 is inserted. When fixing the ground block 51, the fixing nail 511 located at the bottom of the ground block 51 is inserted into the ground, and after fixing the horizontal position of the ground block 51, the ground block 51 pulls the chain 52 to be stable on the ground. The final tightening bolt 512 is inserted so that it can be fixed and no displacement occurs.

In one embodiment of the present invention, the caisson pile overload monitoring device further comprises a reinforcement assembly including two or more reinforcement arms including a support bar 61, a spring 62, a wheel seat 63 and a rotating wheel 64; are fixed to both sides of the lower end of the housing 41, a wheel seat 63 is fixed to the end of the support rod 61 via a spring 62, and two or more rotating wheels 64 are rotatably connected to the wheel seat 63. be done. When the overflow monitoring device is pulled out from the pedestal 3, the reinforcing arms on both sides of the housing 41 are supported by the wall of the pile outer frame 1, and the wheel seat 63 and the pulley are pushed against the wall under the pushing force of the spring 62, and the support rod 61 is pushed out. By laterally supporting the overflow monitoring device through the , it avoids displacement due to lack of support on both the left and right sides after it is pulled out from the base 3 .

In one embodiment of the present invention, the overload monitoring device further comprises a processor, a warning light 76 and a pre-starter, the processor and pre-starter are both located on the housing 41 and the warning light 76 is , is fixed to the upper part of the housing 41, and the speed measuring part, the pre-activation part and the warning light 76 are each electrically connected to the processor. The pre-starter extends to a position slightly lower than the wing 44 to allow rough monitoring of concrete height, and when the poured concrete reaches the pre-starter it triggers the pre-starter and pulls from the pre-starter. A signal is sent to the processor to trigger the warning light 76 and the motor 42 by the processor, at which time the motor 42 rotates the transmission shaft 43 . In this way it is no longer necessary to turn on the power from the beginning of the pouring operation, saving electrical energy. At the same time, the warning light 76 is also triggered, which can alert outside workers early, which is convenient for slowing down the pouring speed and controlling the stopping time of pouring.

In one embodiment of the invention, the pre-actuator comprises a traction sensor 71, a connecting rope 72, a mesh frame 73, a counterweight block 74 and a flat plate 75, the traction sensor 71 being located inside the housing 41. , the monitoring end of the traction force sensor 71 is connected to one end of the connecting rope 72, the other end of the connecting rope 72 is connected to the mesh frame 73, the counterweight block 74 is placed on the mesh frame 73, and the flat plate 75 is fixed to the bottom wall of the mesh frame 73, and the traction force sensor 74 is electrically connected to the processor. If the concrete height does not reach the slab 75, the traction sensor 71 detects that the weight between the mesh frame 73 and the counterweight block 74 is stable. When the poured concrete reaches the slab 75, the slab 75 is pushed up by the concrete below, and when the traction force sensor 74 detects weight reduction, a signal is sent to the processor, and when the processor receives the signal, the motor 24 is started, Plays a role in saving electrical energy.

In one embodiment of the present invention, a fixed rod 81 is fixedly installed on the top of the pedestal 3 , a positioning hole 82 is provided in the housing 41 , and the fixed rod 81 is fitted into the positioning hole 82 . In some cases, it may not be necessary to move the pile outer frame 1 during the pouring operation. In this case, the grounding of the grounding block 51 is not required, and the fixing rod 81 is inserted into the positioning hole 82, and the excess pouring monitoring device is used as a pedestal. It should be fixed together. This relatively fixes the position of the overflow monitoring device during use, improving the stability of monitoring.

Other techniques of this embodiment employ known techniques.

The above is only a preferred specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can apply the technical solution of the present invention and its invention to the technical scope disclosed in the present invention. Equivalent substitutions and modifications based on the concept are intended to be covered by the appended claims.

1 Pile outer frame 21 Fixing ring 22 Telescopic rod 23 Fixing block 24 Arc groove 3 Pedestal 41 Housing 42 Motor 43 Transmission shaft 44 Wing 45 Gear ring 46 Monitoring gear 47 Rotation speed detector 48 Tooth hole row 51 Ground block 511 Fixing nail 512 Final tightening bolt 52 Chain 53 First intermediate gear 54 Second intermediate gear 55 Drive gear 61 Support rod 62 Spring 63 Wheel seat 64 Rotating wheel 71 Traction force sensor 72 Connecting rope 73 Mesh frame 74 Counterweight block 75 Flat plate 76 Warning light 81 Fixed rod 82 Positioning hole

Claims (8)

A caisson pile overload monitoring device comprising:
comprising a monitoring unit and a moving unit,
The monitoring part comprises a base (3) including a fixed seat for fixing to the pile mouth pile outer frame (1) of the caisson pile, and an overload monitoring device inserted into the base (3), comprises a ground block (51), a chain (52), a first intermediate gear (53), a second intermediate gear (54) and a drive gear (55), one end of the chain (52) are fixedly connected to the ground block, a first intermediate gear (53) is rotatably connected to the end of said fixed seat, and a second intermediate gear (54) rotates inside the base (3). The drive gear (55) is rotatably connected inside the pedestal (3) and the chain (52) connects the first relay gear (53), the second relay gear (54) and the drive gear (54). Gears (55) mesh in this order,
The overload monitoring device comprises a housing (41), a motor (42), a transmission shaft (43), wings (44), and a speed measuring unit, the motor (42) being connected to the housing (41). one end of the transmission shaft (43) is fixedly connected to the power output end of the motor (42); the blade (44) is fixed to the other end of the transmission shaft (43); , fixed to the pedestal and connected to the transmission shaft (43), the outer wall of the housing (41) is provided with a tooth hole row (48), and the driving gear (55) is connected to the tooth hole row (48). meshed,
A caisson pile overload monitoring device characterized by: The fixed seat is composed of a fixed ring (21) and two or more support arms, and the two or more support arms are evenly provided outside the fixed ring (21), and the support arms are: comprising a telescopic rod (22) and a fixed block (23), the fixed end of the support arm is fixed to the outer wall of the fixed ring (21), the fixed block (23) is fixed to the free end of the support arm, The bottom of the fixed block (23) is provided with an arcuate groove (24), the fixed ring (21) is fitted on the outside of the housing (41), and the first relay gear (53) is located on the fixed block (23) rotatably connected to one of
The caisson pile overload monitoring device according to claim 1, characterized in that: Said speed measuring unit comprises a gear ring (45), a monitoring gear (46), and a speed detector (47), wherein said gear ring (45) is fitted on said drive shaft and monitors said gear (46). ) is fixed to the monitoring end of the speed detection device and meshed with the gear ring (45),
The caisson pile overload monitoring device according to claim 1, characterized in that: A fixing nail (511) is provided at the bottom of the ground block (51), and a through hole through which a final tightening bolt (512) is inserted is provided in the ground block (51),
The caisson pile overload monitoring device according to claim 1, characterized in that: Further comprising a stiffening assembly including two or more stiffening arms including a support bar (61), a spring (62), a wheel seat (63) and a rotating wheel (64), the support bar (61) being connected to the housing (41) The wheel seat (63) is fixed to the end of the support rod (61) via the spring (62), and two or more rotating wheels (64) are fixed to the wheel seat (63) rotatably connected to the
The caisson pile overload monitoring device according to claim 1, characterized in that: Further comprising a processor, a warning light (76), and a pre-startup unit, the processor and the pre-startup unit are both arranged in the housing (41), and the warning light (76) is mounted on the housing (41). fixed to the top, the speed measuring unit, the pre-activation unit and the warning light (76) are each electrically connected to the processor;
The caisson pile overload monitoring device according to claim 1, characterized in that: The preliminary activation part comprises a tractive force sensor (71), a connecting rope (72), a mesh frame (73), a counterweight block (74) and a flat plate (75),
The tractive force sensor (71) is disposed inside the housing (41), the monitoring end of the tractive force sensor (71) is connected to one end of the connection rope (72), and the other end of the connection rope (72) is connected to the mesh frame. (73), the counterweight block (74) is placed on the net frame (73), the flat plate (75) is fixed to the bottom wall of the net frame (73), and the traction force sensor (74) is connected to said electrically connected to the processor,
The caisson pile overload monitoring device according to claim 6, characterized in that: A fixing rod (81) is fixedly installed on the top of the pedestal (3), and a positioning hole (82) is provided in the housing (41). mated to
The caisson pile overload monitoring device according to claim 1, characterized in that:

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