阅读说明：本技术 基于抱桩器液压系统的故障预测方法及抱桩器液压系统 (Pile gripper hydraulic system and fault prediction method based on same ) 是由 吴韩 吴平平 魏千洲 秦昊 刘会涛 张帅君 邓达纮 陈凯欣 马振军 黄记想 于 2020-12-29 设计创作，主要内容包括：本发明公开了一种基于抱桩器液压系统的故障预测方法及抱桩器液压系统,包括如下步骤：采集数据：采集抱桩器的实时数据；筛选变量：将采集的实时数据,筛选出与液压系统相关的变量作为输入,液压系统是否发生故障作为输出；数据集拆分：将数据集拆分为训练集和测试集；构建神经网络：根据数据集构建深度神经网络模型；数据集训练：将训练样本导入神经网络模型进行训练；数据预测：将测试样本导入神经网络模型并输出预测结果；输出判断结果；本申请旨在提供一种基于抱桩器液压系统的故障预测方法及抱桩器液压系统,能够预测可能发生的液压故障。(The invention discloses a fault prediction method based on a hydraulic system of a pile gripper and the hydraulic system of the pile gripper, which comprises the following steps: collecting data: collecting real-time data of the pile gripper; screening variables: screening out variables related to the hydraulic system as input and judging whether the hydraulic system breaks down or not as output according to the collected real-time data; splitting a data set: splitting a data set into a training set and a test set; constructing a neural network: constructing a deep neural network model according to the data set; training a data set: leading the training sample into a neural network model for training; and (3) data prediction: leading the test sample into a neural network model and outputting a prediction result; outputting a judgment result; the application aims to provide a fault prediction method based on a pile gripper hydraulic system and the pile gripper hydraulic system, which can predict the possible hydraulic fault.)

1. A fault prediction method based on a hydraulic system of a pile gripper is characterized by comprising the following steps:

collecting data: collecting real-time data of the pile gripper;

screening variables: screening out variables related to the hydraulic system as input and judging whether the hydraulic system breaks down or not as output according to the collected real-time data;

splitting a data set: splitting a data set into a training set and a test set;

constructing a neural network: constructing a deep neural network model according to the data set;

training a data set: leading the training sample into a neural network model for training;

and (3) data prediction: leading the test sample into a neural network model and outputting a prediction result;

and outputting a judgment result.

2. The pile-embracing hydraulic system-based fault prediction method according to claim 1, wherein in the step of screening variables, the collected real-time data variables comprise: the upper displacement of telescopic roller hydro-cylinder, telescopic roller hydro-cylinder upper flow, telescopic roller hydro-cylinder upper pressure, telescopic roller hydro-cylinder lower floor's displacement, telescopic roller hydro-cylinder lower floor's flow, telescopic roller hydro-cylinder lower floor's pressure, the hydro-cylinder displacement that opens and shuts, the hydro-cylinder flow that opens and shuts, the hydro-cylinder pressure that opens and shuts, cross system hydro-cylinder displacement that slides, main oil pump system pressure, the oil tank temperature, the oil tank liquid level height, main oil pump motor speed, vice oil pump motor speed, the left side is embraced the arm pin joint and is deformed, the right side is embraced the arm pin joint and is deformed.

3. The pile-embracing hydraulic system-based fault prediction method according to claim 1, wherein in the step of constructing the neural network, an internal calculation formula for constructing the deep neural network comprises:

input layer- > hidden layer, hidden layer- > calculation of output layer:

I_j＝∑_iW_ijX_i+θ_j；

wherein W_ijAs a weight, θ_jIs inclined toSetting value, X_iTo input, O_jFor output, I is the node number of the previous network, j is the node number of the next network, I_jFor the result of the operation, e is a natural constant.

4. The pile-embracing hydraulic system-based fault prediction method according to claim 1, wherein in the step of constructing the neural network, an internal calculation formula for constructing the deep neural network comprises:

updating and calculating the weight and the threshold value:

dW_ij＝dI_j*X_i；

dθ_j＝dI_j；

W＝W_ij-α*dW_ij；

θ＝θ_j-α*dθ_j；

where d is the derivative, α is the learning rate, W_ijAs a weight, θ_jIs an offset value, X_iFor input, I is the node number of the previous network, j is the node number of the next network, I_jIs the result of the operation.

5. The pile-embracing hydraulic system-based fault prediction method according to claim 1, wherein in the step of constructing the neural network, an internal calculation formula for constructing the deep neural network comprises:

the loss function is:

cost＝-y*log(y’)-(1-y)log(1-y’)；

where y is the actual output value and y' is the output value calculated by the neural network, and the iteration is stopped when cost < 0.04.

6. A hydraulic system of a pile gripper is characterized by comprising a moving seat, a moving mechanism, a mounting frame, a holding unit and a telescopic roller unit;

the moving mechanism is arranged on a foundation, the moving seat is arranged on the moving mechanism, and the moving mechanism drives the moving seat to move along the direction of a horizontal double shaft;

the mounting frame is arranged on the movable seat, at least two holding units are arranged, and the at least two holding units are arranged at intervals along the vertical direction;

the telescopic roller unit is arranged on the holding unit, and the output end of the telescopic roller unit is opposite to the steel pile.

7. A pile gripper hydraulic system according to claim 6, wherein the mounting frame comprises a plurality of hinge seats; the clasping unit comprises a left clasping arm, a right clasping arm, a front clasping arm and a clasping oil cylinder;

the number of the holding oil cylinders is two, the holding oil cylinders are hinged with the mounting frame, the output end of one of the holding oil cylinders is hinged with the outer wall of the left holding arm, and the output end of the other holding oil cylinder is hinged with the outer wall of the right holding arm;

one end of the left embracing arm is hinged with the hinge seat on the left side, and one end of the right embracing arm is hinged with the hinge seat on the right side;

one end of the front embracing arm is hinged with one end of the right embracing arm, and the other end of the front embracing arm is opposite to one end of the left embracing arm;

the arm is embraced with the articulated shaft of articulated seat, preceding armful arm with the articulated shaft of arm is embraced on the right side and the arm is embraced on the right side with the articulated shaft of articulated seat parallels.

8. The pile gripper hydraulic system according to claim 6, wherein the mounting frame is provided with a first mounting hole, the clasping unit is provided with a plurality of second mounting holes, and the telescopic roller units are provided in plurality and are respectively arranged in the corresponding first mounting hole and the second mounting hole; each telescopic roller unit is distributed at equal intervals.

9. The pile gripper hydraulic system according to claim 8, wherein the telescopic roller unit comprises a mounting ring, a sliding sleeve, a fixed sleeve, a telescopic cylinder, a connecting seat and a limiting roller;

the mounting ring is arranged on the periphery of the first mounting hole or the periphery of the second mounting hole, the fixed sleeve is connected with the mounting ring, the sliding sleeve is arranged in the first mounting hole or the second mounting hole in a sliding mode, one end of the sliding sleeve extends into the fixed sleeve, the other end of the sliding sleeve is connected with the connecting seat, the telescopic oil cylinder is arranged in the fixed sleeve, the output end of the telescopic oil cylinder is connected with the sliding sleeve, and the limiting roller wheel is rotatably arranged on the connecting seat;

and the limiting rollers of the telescopic roller units are matched with the positioning steel piles.

10. The pile gripper hydraulic system according to claim 6, wherein the moving mechanism comprises a horizontal transverse guide rail, a horizontal longitudinal guide rail, a horizontal transverse cylinder, a horizontal longitudinal cylinder, a moving frame, a first guide wheel assembly and a second guide wheel assembly;

the first guide wheel assembly is arranged on the lower surface of the moving frame and is in sliding connection with the horizontal transverse guide rail;

one end of the horizontal transverse cylinder is connected with the horizontal transverse guide rail, and the output end of the horizontal transverse cylinder is connected with the first guide wheel assembly;

the horizontal longitudinal guide rail is arranged on the moving frame, the second guide wheel assembly is arranged on the lower surface of the moving seat, and the second guide wheel assembly is connected with the horizontal longitudinal guide rail in a sliding manner;

one end of the horizontal longitudinal cylinder is connected with the horizontal longitudinal guide rail, and the output end of the horizontal longitudinal cylinder is connected with the second guide wheel assembly.

Technical Field

The invention relates to the technical field of offshore wind power equipment, in particular to a pile gripper hydraulic system and a fault prediction method based on the pile gripper hydraulic system.

Background

The industrial big data is data generated in industrial field informatization application, and comprises information management system data, machine equipment data and external data. The industrial big data technology integrates data acquisition, data storage, data analysis, data mining and data visualization, and the industrial system has intelligent functions such as description, diagnosis, prediction, decision, control and the like by applying the advanced big data technology and throughout various links such as industrial design, industry, production, management, service and the like.

The pile gripper is professional equipment for solving the pile driving construction difficulty of an offshore wind power foundation steel pipe pile (hereinafter referred to as a steel pile), and consists of a mechanism system, a hydraulic system and an electrical control system. The device is used for position adjustment and holding guidance in the pile dropping process of the fan steel pile so as to keep the proper position of the steel pile unchanged; the perpendicularity of the steel pile can be adjusted under the working condition of sinking the steel pile at the bottom; can guide, assist and right and hang down straightness and adjust when the pile driving operating mode. Due to the fact that the pile embracing device operates on the sea and is influenced by various environmental factors such as sea waves, equipment can be degraded over time to cause faults. At present, no method capable of predicting the fault of the hydraulic system of the pile gripper exists in the hydraulic system of the pile gripper.

Disclosure of Invention

The invention aims to provide a fault prediction method based on a hydraulic system of a pile gripper and the hydraulic system of the pile gripper, which can predict a possible hydraulic fault.

In order to achieve the purpose, the invention adopts the following technical scheme: a fault prediction method based on a hydraulic system of a pile gripper comprises the following steps:

collecting data: collecting real-time data of the pile gripper;

screening variables: screening out variables related to the hydraulic system as input and judging whether the hydraulic system breaks down or not as output according to the collected real-time data;

splitting a data set: splitting a data set into a training set and a test set;

constructing a neural network: constructing a deep neural network model according to the data set;

training a data set: leading the training sample into a neural network model for training;

and (3) data prediction: leading the test sample into a neural network model and outputting a prediction result;

and outputting a judgment result.

Preferably, in the step of screening variables, the collected real-time data variables include: the upper displacement of telescopic roller hydro-cylinder, telescopic roller hydro-cylinder upper flow, telescopic roller hydro-cylinder upper pressure, telescopic roller hydro-cylinder lower floor's displacement, telescopic roller hydro-cylinder lower floor's flow, telescopic roller hydro-cylinder lower floor's pressure, the hydro-cylinder displacement that opens and shuts, the hydro-cylinder flow that opens and shuts, the hydro-cylinder pressure that opens and shuts, cross system hydro-cylinder displacement that slides, main oil pump system pressure, the oil tank temperature, the oil tank liquid level height, main oil pump motor speed, vice oil pump motor speed, the left side is embraced the arm pin joint and is deformed, the right side is embraced the arm pin joint and is deformed.

Preferably, in the step of constructing a neural network, the internal calculation formula for constructing a deep neural network includes:

input layer- > hidden layer, hidden layer- > calculation of output layer:

I_j＝∑_iW_ijX_i+θ_j；

wherein W_ijAs a weight, θ_jIs an offset value, X_iTo input, O_jFor output, I is the node number of the previous network, j is the node number of the next network, I_jFor the result of the operation, e is a natural constant.

Preferably, in the step of constructing a neural network, the internal calculation formula for constructing a deep neural network includes:

updating and calculating the weight and the threshold value:

dW_ij＝dI_j*X_i；

dθ_j＝dI_j；

W＝W_ij-α*dW_ij；

θ＝θ_j-α*dθ_j；

where d is the derivative, α is the learning rate, W_ijAs a weight, θ_jIs an offset value, X_iFor input, I is the node number of the previous network, j is the node number of the next network, I_jIs the result of the operation.

Preferably, in the step of constructing a neural network, the internal calculation formula for constructing a deep neural network includes:

the loss function is:

cost＝-y*log(y’)-(1-y)log(1-y’)；

where y is the actual output value and y' is the output value calculated by the neural network, and the iteration is stopped when cost < 0.04.

A hydraulic system of a pile gripper comprises a moving seat, a moving mechanism, a mounting frame, a holding unit and a telescopic roller unit; the moving mechanism is arranged on a foundation, the moving seat is arranged on the moving mechanism, and the moving mechanism drives the moving seat to move along the direction of a horizontal double shaft; the mounting frame is arranged on the movable seat, at least two holding units are arranged, and the at least two holding units are arranged at intervals along the vertical direction; the telescopic roller unit is arranged on the holding unit, and the output end of the telescopic roller unit is opposite to the steel pile.

Preferably, the mounting rack comprises a plurality of hinge seats; the clasping unit comprises a left clasping arm, a right clasping arm, a front clasping arm and a clasping oil cylinder; the number of the holding oil cylinders is two, the holding oil cylinders are hinged with the mounting frame, the output end of one of the holding oil cylinders is hinged with the outer wall of the left holding arm, and the output end of the other holding oil cylinder is hinged with the outer wall of the right holding arm; one end of the left embracing arm is hinged with the hinge seat on the left side, and one end of the right embracing arm is hinged with the hinge seat on the right side; one end of the front embracing arm is hinged with one end of the right embracing arm, and the other end of the front embracing arm is opposite to one end of the left embracing arm; the arm is embraced with the articulated shaft of articulated seat, preceding armful arm with the articulated shaft of arm is embraced on the right side and the arm is embraced on the right side with the articulated shaft of articulated seat parallels.

Preferably, the mounting frame is provided with a first mounting hole, the enclasping unit is provided with a plurality of second mounting holes, the telescopic roller units are provided with a plurality of telescopic roller units, and each telescopic roller unit is respectively arranged in the corresponding first mounting hole and the corresponding second mounting hole; each telescopic roller unit is distributed at equal intervals.

Preferably, the telescopic roller unit comprises a mounting ring, a sliding sleeve, a fixed sleeve, a telescopic oil cylinder, a connecting seat and a limiting roller; the mounting ring is arranged on the periphery of the first mounting hole or the periphery of the second mounting hole, the fixed sleeve is connected with the mounting ring, the sliding sleeve is arranged in the first mounting hole or the second mounting hole in a sliding mode, one end of the sliding sleeve extends into the fixed sleeve, the other end of the sliding sleeve is connected with the connecting seat, the telescopic oil cylinder is arranged in the fixed sleeve, the output end of the telescopic oil cylinder is connected with the sliding sleeve, and the limiting roller wheel is rotatably arranged on the connecting seat; and the limiting rollers of the telescopic roller units are matched with the positioning steel piles.

Preferably, the moving mechanism comprises a horizontal transverse guide rail, a horizontal longitudinal guide rail, a horizontal transverse cylinder, a horizontal longitudinal cylinder, a moving frame, a first guide wheel assembly and a second guide wheel assembly; the first guide wheel assembly is arranged on the lower surface of the moving frame and is in sliding connection with the horizontal transverse guide rail; one end of the horizontal transverse cylinder is connected with the horizontal transverse guide rail, and the output end of the horizontal transverse cylinder is connected with the first guide wheel assembly; the horizontal longitudinal guide rail is arranged on the moving frame, the second guide wheel assembly is arranged on the lower surface of the moving seat, and the second guide wheel assembly is connected with the horizontal longitudinal guide rail in a sliding manner; one end of the horizontal longitudinal cylinder is connected with the horizontal longitudinal guide rail, and the output end of the horizontal longitudinal cylinder is connected with the second guide wheel assembly.

This application is through the real-time data of gathering the pile gripper in advance, regards hydraulic system correlation variable as the input, trains through the degree of depth neural network model, and whether output hydraulic system breaks down, and the staff makes timely troubleshooting according to the output judgement result. According to the method and the system, the fault model training based on machine learning is realized, long-term online monitoring is carried out, the alarm threshold value is set, the alarm is immediately carried out when the measured value exceeds the threshold value, prediction is carried out in advance, and possible faults are solved in advance.

According to the method, a deep neural network model of the hydraulic system of the pile-embracing device is established based on a machine learning method, the possible hydraulic faults are predicted, and effective guarantee and health management are made in advance. Meanwhile, the invention can carry out targeted and accurate maintenance guidance on the hydraulic equipment, realize the precise guarantee of the hydraulic system and prevent the occurrence of the faults of the hydraulic system.

Drawings

The drawings are further illustrative of the invention and the content of the drawings does not constitute any limitation of the invention.

FIG. 1 is a flow chart of the algorithm of the present invention;

FIG. 2 is a diagram of a neural network computational process of the present invention;

FIG. 3 is a schematic structural diagram of a hydraulic system of a pile gripper of the present invention;

FIG. 4 is a schematic structural view of a hugging unit of the present invention;

FIG. 5 is a schematic view of the moving mechanism of the present invention;

FIG. 6 is an exploded view of the telescopic roller unit of the present invention;

fig. 7 is a schematic top view of the clasping unit of the present invention.

Wherein: the device comprises a moving seat 1, a moving mechanism 2, a horizontal transverse guide rail 21, a horizontal longitudinal guide rail 22, a horizontal transverse air cylinder 23, a horizontal longitudinal air cylinder 24, a moving frame 25, a first guide wheel assembly 26 and a second guide wheel assembly 27;

the mounting frame 3 and the hinge seat 31; the holding unit 4, a left holding arm 41, a right holding arm 42, a front holding arm 43 and a holding oil cylinder 44;

the telescopic roller unit 5, the mounting ring 51, the sliding sleeve 52, the fixed sleeve 53, the telescopic oil cylinder 54, the connecting seat 55 and the limiting roller 56.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Furthermore, features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between descriptive features, non-sequential, non-trivial and non-trivial.

In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 7, a fault prediction method based on a hydraulic system of a pile gripper includes the following steps:

collecting data: collecting real-time data of the pile gripper;

screening variables: screening out variables related to the hydraulic system as input and judging whether the hydraulic system breaks down or not as output according to the collected real-time data;

splitting a data set: splitting a data set into a training set and a test set;

constructing a neural network: constructing a deep neural network model according to the data set;

training a data set: leading the training sample into a neural network model for training;

and (3) data prediction: leading the test sample into a neural network model and outputting a prediction result;

and outputting a judgment result.

By adopting the mode, the real-time data of the pile gripper is collected in advance, the related variable of the hydraulic system is used as input, the deep neural network model is used for training, whether the hydraulic system breaks down or not is output, and the worker can timely remove the fault according to the output judgment result. According to the method and the system, the fault model training based on machine learning is realized, long-term online monitoring is carried out, the alarm threshold value is set, the alarm is immediately carried out when the measured value exceeds the threshold value, prediction is carried out in advance, and possible faults are solved in advance.

According to the method, a deep neural network model of the hydraulic system of the pile-embracing device is established based on a machine learning method, the possible hydraulic faults are predicted, and effective guarantee and health management are made in advance. Meanwhile, the invention can carry out targeted and accurate maintenance guidance on the hydraulic equipment, realize the precise guarantee of the hydraulic system and prevent the occurrence of the faults of the hydraulic system.

Specifically, in the step of screening variables, the collected real-time data variables include: the upper displacement of telescopic roller hydro-cylinder, telescopic roller hydro-cylinder upper flow, telescopic roller hydro-cylinder upper pressure, telescopic roller hydro-cylinder lower floor's displacement, telescopic roller hydro-cylinder lower floor's flow, telescopic roller hydro-cylinder lower floor's pressure, the hydro-cylinder displacement that opens and shuts, the hydro-cylinder flow that opens and shuts, the hydro-cylinder pressure that opens and shuts, cross system hydro-cylinder displacement that slides, main oil pump system pressure, the oil tank temperature, the oil tank liquid level height, main oil pump motor speed, vice oil pump motor speed, the left side is embraced the arm pin joint and is deformed, the right side is embraced the arm pin joint and is deformed.

The collected real-time data variables are used as input variables, and in the specific implementation process, data of certain months can be selected as training samples, namely reference data, for example, data of 1 month to 9 months can be used as training samples, and data of 10 months to 11 months can be selected as testing samples, namely comparison data.

Specifically, in the step of constructing the neural network, the internal calculation formula for constructing the deep neural network includes:

input layer- > hidden layer, hidden layer- > calculation of output layer:

I_j＝∑_iW_ijX_i+θ_j； (7-1)

wherein W_ijAs a weight, θ_jIs an offset value, X_iTo input, O_jFor output, I is the node number of the previous network, j is the node number of the next network, I_jFor the result of the operation, e is a natural constant.

Preferably, in the step of constructing a neural network, the internal calculation formula for constructing a deep neural network includes:

updating and calculating the weight and the threshold value:

dW_ij＝dI_j*X_i； (7-3)

dθ_j＝dI_j； (7-4)

W＝W_ij-α*dW_ij； (7-5)

θ＝θ_j-α*dθ_j； (7-6)

where d is the derivative, α is the learning rate, W_ijAs a weight, θ_jIs an offset value, X_iFor input, I is the node number of the previous network, j is the node number of the next network, I_jIs the result of the operation.

Preferably, in the step of constructing a neural network, the internal calculation formula for constructing a deep neural network includes:

the loss function is:

cost＝-y*log(y')-(1-y)log(1-y')； (7-7)

and when cost is less than 0.04, stopping iteration, namely, when the difference between the actual value and the predicted value is less than 0.04, stopping iteration.

In this embodiment, the constructed neural network is an 18-27-36-10-2 deep neural network, training samples are introduced, training is performed through an 18-27-36-10-2 deep neural network model, test samples are introduced, and a prediction result is output.

In the specific implementation process, the format example of the data input may be: [ displacement of the upper layer of a telescopic roller oil cylinder, flow of the upper layer of the telescopic roller oil cylinder, pressure of the upper layer of the telescopic roller oil cylinder, displacement of the lower layer of the telescopic roller oil cylinder, flow of the lower layer of the telescopic roller oil cylinder, pressure of the lower layer of the telescopic roller oil cylinder, displacement of an opening and closing oil cylinder, flow of the opening and closing oil cylinder, pressure of the opening and closing oil cylinder, displacement of a cross sliding system oil cylinder, pressure of a main oil pump system, temperature of an oil tank, liquid level height of the oil tank, rotating speed of a main oil pump motor, rotating speed of an auxiliary oil pump motor, deformation of a hinge point of a left arm, deformation of a hinge point of a right arm, and smooth insertion of a cross sliding system bolt ] (1050, 0.003,31.5,1320;

the output format is: [ failure, no failure ] ═ 1, 0.

A hydraulic system of a pile gripper comprises a moving seat 1, a moving mechanism 2, a mounting frame 3, a holding unit 4 and a telescopic roller unit 5;

the moving mechanism 2 is arranged on a foundation, the moving seat 1 is arranged on the moving mechanism 2, and the moving mechanism 2 drives the moving seat 1 to move along the horizontal double-axis direction;

the mounting frame 3 is arranged on the movable seat 1, at least two holding units 4 are arranged, and at least two holding units 4 are arranged at intervals in the vertical direction;

the telescopic roller unit 5 is arranged on the holding unit 4, and the output end of the telescopic roller unit 5 is opposite to the steel pile.

Adopt this kind of structure, through removing seat 1 and the 2 cooperation of moving mechanism, can adjust the position of mounting bracket 3, thereby adjust the position of holding unit 4 tightly, conveniently hold unit 4 tightly and stretch out the steel pile tightly, through the cooperation of a plurality of flexible running roller units 5, can rectify the hookup location of holding unit 4 tightly and steel pile, make the steel pile keep holding unit 4's center department tightly, improve the stability of connection, the position that keeps the steel pile is unchangeable, at the pile driving in-process, can lead to the steel pile, supplementary rightting and the straightness is adjusted that hangs down.

Meanwhile, the mounting frame 3 comprises a plurality of hinge seats 31, and the hinge seats 31 are provided; the clasping unit 4 comprises a left clasping arm 41, a right clasping arm 42, a front clasping arm 43 and a clasping oil cylinder 44;

the number of the holding oil cylinders 44 is two, the holding oil cylinders 44 are hinged to the mounting frame 3, the output end of one holding oil cylinder 44 is hinged to the outer wall of the left holding arm 41, and the output end of the other holding oil cylinder 44 is hinged to the outer wall of the right holding arm 42;

one end of the left embracing arm 41 is hinged to the hinge seat 31 on the left side, and one end of the right embracing arm 42 is hinged to the hinge seat 31 on the right side;

one end of the front embracing arm 43 is hinged with one end of the right embracing arm 42, and the other end of the front embracing arm 43 is opposite to one end of the left embracing arm 41;

the left arm 41 is parallel to the hinge shaft of the hinge seat 31, the front arm 43 is parallel to the hinge shaft of the right arm 42, and the right arm 42 is parallel to the hinge shaft of the hinge seat 31.

By adopting the structure, the left embracing arm 41, the right embracing arm 42, the front embracing arm 43 and the embracing oil cylinder 44 are matched, and the embracing oil cylinder 44 extends to push the left embracing arm 41 or the right embracing arm 42 to rotate, so that the left embracing arm 41 or the right embracing arm 42 tightens and embraces the steel pile, and a good connecting and fixing effect is achieved.

Preferably, the mounting frame 3 is provided with a first mounting hole, the clasping unit 4 is provided with a plurality of second mounting holes, the telescopic roller units 5 are provided with a plurality of telescopic roller units, and each telescopic roller unit 5 is respectively arranged in the corresponding first mounting hole and the corresponding second mounting hole; each of the telescopic roller units 5 is equidistantly distributed.

Specifically, the telescopic roller unit 5 comprises a mounting ring 51, a sliding sleeve 52, a fixed sleeve 53, a telescopic oil cylinder 54, a connecting seat 55 and a limiting roller 56;

the mounting ring 51 is arranged on the periphery of the first mounting hole or the periphery of the second mounting hole, the fixed sleeve 53 is connected with the mounting ring 51, the sliding sleeve 52 is slidably arranged in the first mounting hole or the second mounting hole, one end of the sliding sleeve 52 extends into the fixed sleeve 53, the other end of the sliding sleeve 52 is connected with the connecting seat 55, the telescopic cylinder 54 is arranged in the fixed sleeve 53, the output end of the telescopic cylinder 54 is connected with the sliding sleeve 52, and the limit roller 56 is rotatably arranged on the connecting seat 55;

the limiting rollers 56 of the telescopic roller units 5 are matched with the positioning steel piles.

Adopt this kind of structure, fixed cover 53 and collar 51 are connected, and when flexible hydro-cylinder 54 extended, flexible hydro-cylinder 54's output drove sliding sleeve 52 and removes, and sliding sleeve 52 drives connecting seat 55 and removes towards one side of piling bar, and spacing running roller 56 stretches out with the outer wall contact of piling bar, through adjusting a plurality of flexible running roller units 5 that circumference set up, can lead and assist rightting to the piling bar, avoids the piling bar to take place the skew under the piling bar in-process.

Preferably, the moving mechanism 2 comprises a horizontal transverse guide rail 21, a horizontal longitudinal guide rail 22, a horizontal transverse air cylinder 23, a horizontal longitudinal air cylinder 24, a moving frame 25, a first guide wheel assembly 26 and a second guide wheel assembly 27;

the first guide wheel assembly 26 is arranged on the lower surface of the moving frame 25, and the first guide wheel assembly 26 is slidably connected with the horizontal transverse guide rail 21;

one end of the horizontal transverse cylinder 23 is connected with the horizontal transverse guide rail 21, and the output end of the horizontal transverse cylinder 23 is connected with the first guide wheel assembly 26;

the horizontal longitudinal guide rail 22 is arranged on the moving frame 25, the second guide wheel assembly 27 is arranged on the lower surface of the moving base 1, and the second guide wheel assembly 27 is connected with the horizontal longitudinal guide rail 22 in a sliding manner;

one end of the horizontal longitudinal cylinder 24 is connected with the horizontal longitudinal guide rail 22, and the output end of the horizontal longitudinal cylinder 24 is connected with the second guide wheel assembly 27.

The horizontal transverse guide rail 21 is arranged on a foundation or other infrastructures, the horizontal transverse air cylinder 23 pushes the moving frame 25 to move along the horizontal transverse direction, and the first guide wheel assembly 26 is matched with the horizontal transverse guide rail 21 to play a good guiding role.

The horizontal longitudinal cylinder 24 pushes the moving frame 25 to move along the horizontal longitudinal direction, and the second guide wheel assembly 27 is matched with the horizontal longitudinal guide rail 22 to play a good guiding role.

The position of the mounting frame 3 is adjusted on the same horizontal plane horizontally and horizontally, so that the holding unit 4 is adjusted to be opposite to the steel pile, and good alignment work and positioning effect are achieved.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The technical principle of the present invention is described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive effort, which would fall within the scope of the present invention.