CN213352332U - Workbench for detecting position deviation and alignment of workpiece by using sensor - Google Patents

Abstract

The utility model provides an utilize sensor to detect workstation of work piece positional deviation and alignment, equipment constitutes simply, and is with low costs, efficient. The utility model comprises a sensor component, a numerical control transverse linear motion unit, a numerical control longitudinal linear motion unit, a machine base and a workpiece supporting disc; the numerical control longitudinal linear motion unit is fixedly arranged on the base; the numerical control transverse linear motion unit is arranged on the numerical control longitudinal linear motion unit, and the motion directions of the numerical control longitudinal linear motion unit and the numerical control transverse linear motion unit are mutually vertical; the workpiece supporting disc is arranged on the numerical control transverse linear motion unit; the sensor assembly comprises a sensor bracket and two sensors, and the sensors are arranged on the sensor bracket; the sensing points of the two sensors are positioned on the central axis of the numerical control longitudinal linear motion unit and are arranged in a front-back mode.

Description

Workbench for detecting position deviation and alignment of workpiece by using sensor

Technical Field

The utility model relates to an utilize sensor to detect workstation of work piece positional deviation and alignment.

Background

For various automatic production equipment and automatic production lines, the starting end of the process flow is workpiece loading, and when the workpiece is loaded, the workpiece is required to be accurately positioned so as to realize the subsequent automatic process. Flexible workpieces or thin-sheet workpieces and other types of workpieces are difficult to accurately position in a mechanical limiting mode such as a clamp, a guide piece, a rigid stop block and the like, so that the workpieces inevitably have position deviation after being loaded and need to be aligned.

In the prior art, a visual recognition system is mostly adopted, and the workpiece is aligned by comparing the difference between the actual position and the ideal position of the workpiece. While the problem of workpiece position detection is solved, there are some other problems at the same time: first, vision recognition systems are expensive, resulting in high equipment costs; secondly, the recognition success rate of the visual recognition system is greatly influenced by the product and the surrounding environment, and one workpiece is often compared for many times, so that the normal operation and the production efficiency of equipment are directly influenced. Thirdly, for large-sized workpieces and long-strip-shaped workpieces, the visual recognition system needs to be spliced by a plurality of cameras, so that the recognition success rate is reduced, and the equipment cost is increased.

In the prior art, a plurality of photoelectric sensors are mounted on a robot to align a workpiece. Although replacing the visual recognition system with a photosensor partially reduces the cost of the device, there are other problems: firstly, only the alignment of a workpiece with a rectangular or square outline can be realized; secondly, robots are expensive, resulting in higher equipment costs; third, the robot control system is complex.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the above-mentioned not enough that exists among the prior art, and provide a workstation that utilizes sensor to detect work piece positional deviation and alignment that structural design is reasonable, equipment constitutes simply, and is with low costs, efficient.

The utility model provides a technical scheme that above-mentioned problem adopted is: a workbench for detecting position deviation and alignment of a workpiece by using a sensor is characterized in that: the device comprises a sensor component, a numerical control transverse linear motion unit, a numerical control longitudinal linear motion unit, a machine base and a workpiece supporting disc; the numerical control longitudinal linear motion unit is fixedly arranged on the base; the numerical control transverse linear motion unit is arranged on the numerical control longitudinal linear motion unit, and the motion directions of the numerical control longitudinal linear motion unit and the numerical control transverse linear motion unit are mutually vertical; the workpiece supporting disc is arranged on the numerical control transverse linear motion unit; the sensor assembly comprises a sensor bracket and two sensors, and the sensors are arranged on the sensor bracket; the sensing points of the two sensors are positioned on the central axis of the numerical control longitudinal linear motion unit and are arranged in a front-back mode.

The workstation still be provided with numerical control rotation mechanism, numerical control rotation mechanism installs on the horizontal linear motion unit of numerical control, work piece supporting disk and numerical control rotation mechanism are connected, numerical control rotation mechanism drive work piece supporting disk rotates.

The workpiece supporting disc of the utility model is a vacuum chuck, an electromagnetic chuck or a pressing plate type workpiece supporting disc.

The sensor be photoelectric sensor, optical fiber sensor, laser sensor, ultrasonic sensor or be proximity switch.

The actuating mechanism of the numerical control transverse linear motion unit and the numerical control longitudinal linear motion unit is a screw nut mechanism, a gear rack mechanism, a chain transmission mechanism, a belt transmission mechanism, a cam guide rod mechanism, a connecting rod mechanism, an oil cylinder, a linear motor or a linear motion module with a position sensing function.

The utility model discloses still include control system, sensor, numerical control rotation mechanism, the horizontal linear motion unit of numerical control, the vertical linear motion unit of numerical control all are connected with the control system electricity.

The utility model discloses a numerical control swing mechanism which comprises a motor and a motor bracket; the motor support is arranged on the numerical control transverse linear motion unit, the motor is vertically and upwards arranged on the motor support, and the workpiece supporting disc is arranged on a motor output shaft of the motor.

Utilize sensor to detect work piece positional deviation and workstation of alignment, its characterized in that: the motor is a brake motor, a stepping motor or a servo motor with a rotary encoder.

Utilize sensor to detect work piece positional deviation and workstation of alignment, its characterized in that: the control system is an industrial personal computer or a PLC.

Compared with the prior art, the utility model, have following advantage and effect: the sensor is used for detecting the position deviation of the workpiece, so that the recognition system and the control system are greatly simplified, the device is suitable for workpieces with various shapes such as triangle, quadrangle, polygon, arc, circle, ellipse and the like, and is particularly suitable for occasions such as flexible workpieces, thin sheet workpieces and the like where the workpieces are difficult to be accurately positioned through mechanical limiting modes such as clamps, guide blocks, rigid stop blocks and the like; the workbench for detecting the position deviation and alignment of the large-sized workpiece and the elongated workpiece by using the sensor also has certain advantages, the workpiece is inspected and aligned by using the conventional numerical control motion unit, the whole machine is simple in structure, reliable in operation and high in accuracy, the equipment cost is greatly reduced, and the alignment efficiency is improved.

Drawings

Fig. 1a is a schematic structural diagram of a workbench with a numerical control swing mechanism according to an embodiment of the present invention.

FIG. 1b is a schematic side view of the structure of FIG. 1 a.

Fig. 1c is a schematic structural view of a workbench without a numerical control swing mechanism according to an embodiment of the present invention.

FIG. 1d is a schematic side view of the structure of FIG. 1 c.

Fig. 2a is a first schematic view of a plane coordinate system of a workbench and a workpiece loading state according to an embodiment of the present invention, in which an upper portion of a workpiece is shifted.

Fig. 2b is a schematic diagram of a plane coordinate system of the worktable and a workpiece loading state according to an embodiment of the present invention, in which the lower part of the workpiece is shifted.

Fig. 3a is a schematic diagram of alignment of a workpiece whose detected edge is a straight line according to an embodiment of the present invention, in which a point on the detected edge of the workpiece is detected at a detection point of a first sensor.

Fig. 3b is a schematic diagram of alignment of a workpiece whose detected edge is a straight line according to an embodiment of the present invention, in which a point on the detected edge of the workpiece is detected at a detection point of a second sensor.

Fig. 3c is a schematic diagram of alignment of the workpiece whose detected edge is a straight line according to the embodiment of the present invention, in which the inspection operation is finished.

Fig. 3d is a schematic diagram illustrating alignment of a workpiece whose detected edge is a straight line according to an embodiment of the present invention, in which the deflection angle of the workpiece is eliminated.

Fig. 3e is a schematic diagram of alignment of the workpiece whose detected edge is a straight line according to the embodiment of the present invention, in which the transverse alignment of the workpiece is completed.

Fig. 3f is an alignment schematic diagram six of the workpiece whose detected edge is a straight line according to the embodiment of the present invention, in which the adjacent edge of the detected edge of the workpiece is detected at the detection point of the second sensor during the vertical alignment.

Fig. 4a is a schematic diagram illustrating the alignment result of the edge-to-edge alignment and the center line alignment of the workpiece according to the embodiment of the present invention.

Fig. 4b is a schematic view of the geometric relationship of the workpiece to the center line during transverse alignment according to the embodiment of the present invention.

Fig. 4c is a schematic view of the geometric relationship of the workpiece to the center line in the longitudinal alignment according to the embodiment of the present invention.

Fig. 5a is a schematic view illustrating an alignment principle of a workpiece whose detected edge is circular arc or circular shape according to an embodiment of the present invention, in which a worktable is at an initial position.

Fig. 5b is a schematic diagram of alignment of a workpiece whose detected edge is circular arc or circular shape according to the embodiment of the present invention, in which a point on the detected edge of the workpiece is detected at a detection point of the first sensor.

Fig. 5c is a schematic diagram of alignment of a workpiece whose detected edge is circular arc or circular, according to the embodiment of the present invention, in which a point on the detected edge of the workpiece is detected at a detection point of the second sensor.

Fig. 5d is a schematic diagram of the alignment of the workpiece whose detected edge is circular arc or circular shape according to the embodiment of the present invention, in which the inspection operation is finished.

Fig. 6a is a schematic view illustrating the alignment of a workpiece whose detected edge is an oval shape according to the embodiment of the present invention, in which the workbench is in an initial position and the upper portion of the workpiece is shifted.

Fig. 6b is a schematic diagram of alignment of a workpiece whose detected edge is an oval shape according to an embodiment of the present invention, in which a point on the detected edge of the workpiece is detected at a detection point of a first sensor.

Fig. 6c is a schematic diagram of alignment of a workpiece whose detected edge is an oval shape according to an embodiment of the present invention, in which a point on the detected edge of the workpiece is detected at a detection point of a second sensor.

Fig. 6d is a schematic diagram of alignment of the workpiece whose detected edge is oval according to the embodiment of the present invention, in which another point on the detected edge of the workpiece is detected at the detection point of the first sensor.

Fig. 6e is a schematic diagram of alignment of a workpiece with an oval detected edge according to an embodiment of the present invention, in which another point on the detected edge of the workpiece is detected at a detection point of the second sensor.

Fig. 6f is a diagram six of the alignment principle of the workpiece whose detected edge is oval according to the embodiment of the present invention, in which the inspection operation is finished.

Fig. 6g is a schematic diagram illustrating an alignment of a workpiece with an oval edge according to an embodiment of the present invention, wherein the deflection angle of the workpiece is eliminated.

Fig. 6h is an eight schematic diagram of the alignment of the workpiece with the oval detected edge according to the embodiment of the present invention, in which the lower portion of the workpiece is shifted.

In the above drawings, the dotted line frame G at the upper part of the numerical control longitudinal linear motion unit is an ideal position of the workpiece at the next station.

Detailed Description

The present invention will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present invention and are not intended to limit the present invention.

Utilize sensor to detect workstation of 6 position deviations of work piece and alignment, including sensor module 1, the horizontal linear motion unit 3 of numerical control, the vertical linear motion unit 4 of numerical control, control system, frame 5, work piece supporting disk 7, the horizontal linear motion unit support of numerical control 8 and the vertical linear motion unit support of numerical control 9

The numerical control longitudinal linear motion unit 4 is fixedly arranged on the machine base 5 through a numerical control longitudinal linear motion unit bracket 9.

The numerical control transverse linear motion unit 3 is arranged on the numerical control longitudinal linear motion unit 4 through a numerical control transverse linear motion unit bracket 8 and moves linearly along with the numerical control longitudinal linear motion unit 4. The movement of the numerical control longitudinal linear motion unit 4 is realized by a conventional linear motion mechanism with a position sensing function, and the numerical control transverse linear motion unit 3 is dragged to do linear motion. The motion directions of the numerical control longitudinal linear motion unit 4 and the numerical control transverse linear motion unit 3 are mutually vertical.

The workpiece supporting disk 7 is arranged on the numerical control transverse linear motion unit 3 and moves linearly along with the numerical control transverse linear motion unit 3. The workpiece 6 is fixedly arranged on the workpiece supporting disc 7, and in order to prevent the workpiece 6 and the workpiece supporting disc 7 from generating relative motion, the workpiece supporting disc 7 can be a vacuum chuck or an electromagnetic chuck, and can also adopt a pressing plate and other forms to fix the workpiece 6.

The sensor assembly 1 comprises a sensor support 11 and two sensors 12, wherein the two sensors 12 are a first sensor 121 and a second sensor 122, and the first sensor 121 and the second sensor 122 are both arranged on the sensor support 11. The mutual position relationship between the first sensor 121 and the second sensor 122 is fixed, and the sensing points of the first sensor 121 and the second sensor 122 are both located on the central axis of the longitudinal linear motion unit 4 and are arranged in a front-back manner. The sensor 12 is a photoelectric sensor, a fiber optic sensor, a laser sensor, an ultrasonic sensor, or a proximity switch.

The linear motion of the numerical control transverse linear motion unit 3 and the numerical control longitudinal linear motion unit 4 is realized by a conventional linear motion mechanism with a position sensing function, and thus, the actuating mechanisms of the numerical control transverse linear motion unit 3 and the numerical control longitudinal linear motion unit 4 can be a screw nut mechanism, a gear rack mechanism, a chain transmission mechanism, a belt transmission mechanism, a cam guide rod mechanism, a connecting rod mechanism, an oil cylinder, a linear motor or a linear motion module with a position sensing function.

When the workbench is used for a circular or arc-shaped workpiece 6, the workpiece supporting disc 7 is directly installed and fixed on the numerical control transverse linear motion unit 3 and linearly moves along with the numerical control transverse linear motion unit 3.

When the workbench is used for a non-perfect-circle and non-circular-arc workpiece 6, the workbench is also provided with a numerical control swing mechanism 2, and a workpiece supporting disc 7 is arranged on the numerical control transverse linear motion unit 3 through the numerical control swing mechanism 2. The numerical control swing mechanism 2 includes a motor 21 and a motor bracket 22. The motor bracket 22 is arranged on the numerical control transverse linear motion unit 3, and the numerical control transverse linear motion unit 3 drives the numerical control rotary mechanism 2 to do linear motion. The motor 21 is vertically upwardly mounted on the motor bracket 22. The workpiece supporting disk 7 is mounted on a motor output shaft of the motor 21, and the motor output shaft of the motor 21 drives the workpiece supporting disk 7 to rotate. The motor 21 is a brake motor, a stepping motor or a servo motor with a rotary encoder.

The sensor 12, the numerical control slewing mechanism 2, the numerical control transverse linear motion unit 3 and the numerical control longitudinal linear motion unit 4 are all electrically connected with a control system. The control system is an industrial personal computer or a PLC.

A method for detecting position deviation and alignment of a workpiece 6 by using a sensor comprises the following steps:

setting: x₁Axis, Y₁The axis being the centre line of the workpiece-supporting disc 7, O₁The point is the rotation center point, X, of the workpiece supporting disk 7₁Axis perpendicular to Y₁Axis, and X₁Axis and Y₁The axis intersecting at O₁Point; the X axis is the central axis of the numerical control transverse linear motion unit 3 and is connected with the X axis₁The axes are overlapped; the Y axis is the central axis of the numerical control longitudinal linear motion unit 4, and Y₁The axes are parallel, and the Y axis and the X axis are perpendicularly intersected at the O point; point a is the sensing point of the first sensor 121, point B is the sensing point of the second sensor 122, both points a and B are on the Y axis, the distance between points A, B is L, and the distance between point a and point O is equal to the distance between point B and point O in the initial state (i.e., the loading state); the detected edge is set as the edge which is detected firstly by the workpiece 6 when the numerical control transverse linear motion unit 3 moves in the process of delivery inspection.

The detection position deviation and alignment of the workpiece 6 with the detected edge as a straight line comprises the following steps:

(1) setting: x₂The shaft being through O₁The point is vertical to the axis of the detected edge of the workpiece, and the vertical foot is f; y is₂The shaft being through O₁The axis of the point is parallel to the detected edge of the workpiece; a. b, c and d are four vertexes of the quadrilateral workpiece 6, ab is a detected edge, the detected edge and X₁The intersection of the axes is e.

(2) The alignment process comprises the following steps:

after the workpiece 6 is loaded, there are three dimensional deviations: workpiece 6 and Y₁O₁X₁Deflection angle β, i.e. Y, of a coordinate system₂And Y₁The included acute angle, the position deviation of the workpiece 6 in the X axial direction, the position deviation of the workpiece 6 in the Y axial direction and the alignment process are processes for eliminating the deviation of three dimensions of the workpiece 6, and the alignment action comprises the following steps:

(21) the inspection process comprises the following steps:

fig. 2a shows the initial position of the table, in which the workpiece 6 is mounted on the workpiece support tray 7 and secured, and then the inspection is triggered: the numerically controlled vertical linear motion unit 4 is not moved, and the numerically controlled horizontal linear motion unit 3 is moved in the reverse direction (leftward in the drawing) toward the X axis, so that the workpiece 6 in the workpiece support tray 7 is moved to the sensor sensing area, and a point a' on the detected side of the workpiece is detected at a point a of the first sensor 121 (see fig. 3a), at which point Y is detected₁Distance S between axis and Y axis₁Is detected asA' point and O on the edge₁The X axial distance of the points; thereafter, the numerically controlled lateral rectilinear motion unit 3 continues to move the workpiece support tray 7, and another point B' on the detected side of the workpiece is detected at point B of the second sensor 122 (see FIG. 3B), and likewise, at this time Y₁Distance S between axis and Y axis₂I.e. the B' point and the O point on the detected edge of the workpiece₁X axial distance of points.

Initial position Y of workpiece 6 during loading₁Distance between axis and Y-axis (i.e. O point to O point)₁The distance of the points) is determined so that the control system can determine the distance based on the time when the second point on the detected edge of the workpiece is detected (in this case point B'), point O₁Judging O point and O point according to the displacement value of the point₁Positional relationship of points (whether O point is on the left or O₁Point at left side), and according to the judged result, the numerical control transverse linear motion unit 3 continues to move the workpiece support disk 7 until O₁Coincident with point O, Y₁The axis coincides with the Y-axis and the submission is finished (see FIG. 3 c). According to S₁And S₂The distance S in X direction between point A 'and B' can be calculated₁-S₂Since the distance L between points a and B is known and fixed, the control system can calculate the yaw angle β of the workpiece 6 as:

according to the geometric relationship, the detected edge O can be obtained₁The distance K of the points is:

after the K value is determined, the workpiece is detected to be Y₂O₁X₂X in a coordinate system₂The coordinates on the axes are then determined.

The inspection process is performed when the workpiece 6 is deflected in the direction shown in fig. 2a, and when the workpiece 6 is deflected in the direction shown in fig. 2B, a point B' on the ab side is detected first at the point B in the second sensor 122, and then detected at the point a in the first sensor 121Detecting another point A' on the ab-side of the workpiece 6, in this case the deflection angle beta and the detected edge O₁The calculation principle of the distance K of the points is the same, and the control system can judge the direction of the angular deviation of the workpiece 6 only according to the sequence that the first sensor 121 and the second sensor 122 detect the workpiece 6, that is: when the first sensor 121 detects a point on the ab edge first and the deflection angle is found, the numerical control swing mechanism 2 rotates clockwise to eliminate the deflection angle beta of the workpiece 6; and when the second sensor 122 detects a point on the ab edge first and the deflection angle is found, the numerical control slewing mechanism rotates anticlockwise to eliminate the deflection angle beta of the workpiece 6.

(22) Deflection angle alignment process:

the control system sends the rotation direction and the rotation angle value, namely the numerical value of the deflection angle beta to the numerical control rotation mechanism 2 according to the detection and calculation results, the motor of the numerical control rotation mechanism 2 rotates according to the instruction, and when the rotation stops, the Y axis and the Y axis₁Axis, Y₂The axes being coincident, Y₂O₁X₂Coordinate system, Y₁O₁X₁The coordinate system and the YOX coordinate system coincide and the deflection angle of the work piece 6 is eliminated (see fig. 3d), at which time the work piece is detected parallel to the Y-axis and at a distance K from the Y-axis and is detected at the Y-axis₂O₁X₂X in a coordinate system₂The coordinate on the axis, i.e. the coordinate of the detected edge of the workpiece on the X axis in the YOX coordinate system, and the coordinate value is X_K。

Under the extreme condition, the workpiece 6 has no deflection angle, in this state, the two sensors 12 can simultaneously detect 2 points on the detected edge of the workpiece and simultaneously send a message, and the control system skips the deflection angle alignment process and directly starts the transverse alignment process.

(23) Transverse alignment process:

the deflection angle alignment is completed, the horizontal alignment of the workpiece 6 is automatically started by the workbench, and the horizontal alignment can be divided into opposite side alignment, center line alignment or center point alignment:

aligning the opposite edges: after alignment, the workpieces 6 of different specifications are all aligned by making the distance from the detected edge ab to the Y axis in the X axial direction and the workpieces 6In the ideal position, the distance from the ab-side to the Y-axis in the X-axis direction is the same, and is H. When the workpiece 6 is at the ideal position of the next station, the detected edge is parallel to the Y axis and has a distance H from the Y axis, and the coordinate value of the detected edge on the X axis is X_H. The numerical control transverse linear motion unit 3 acts to ensure that the workpiece 6 moves by a distance | x_K-x_HCompleting the transverse alignment of the workpiece 6 (see fig. 3 e); extreme case x_KAnd x_HAnd if so, the numerical control transverse linear motion unit 3 does not perform transverse alignment on the workpiece 6.

Centering the center line: according to different subsequent processes of the workpiece 6, it is often necessary to align the center line of the workpiece 6, that is, after alignment of workpieces 6 of different specifications, the center line E of the workpiece 6 and the ideal center line E 'of the workpiece 6 are all on the same straight line, fig. 4a is a comparison of the results of the alignment of the opposite side and the alignment of the center line, where F is the position of the detected side when the workpiece 6 is in the ideal position, and F' is the position of the center line when the workpiece 6 is in the ideal position. In FIG. 4b, the K value and x are shown from the above process_KIt has been found that for workpieces 6 of different specifications, the distance T from the detected edge ab to the center line of the workpiece 6 is known (workpieces 6 are of different specifications and have different values of T), and the inspection process of the workpiece 6 reveals that the center line of the workpiece 6 is located on the right side of the detected edge of the workpiece, and the coordinate value X of the center line on the X axis_TThen determining; when the workpiece 6 is at the ideal position of the next station, the distance from the central line to the Y axis in the X axis direction is P, and the coordinate value on the X axis is X_PThe numerical control transverse linear motion unit 3 acts to make the central line of the workpiece 6 move by a distance | x_P-x_TThe transverse centering center line of the workpiece 6 is aligned; extreme case x_TAnd x_PAnd if the two positions are the same, the numerical control transverse linear motion unit does not perform transverse alignment on the workpiece 6.

Centering a center point: the centering method of the work 6 with respect to the center point is similar to the centering method of the work 6 with respect to the center line: from the above process, K and x_KIt has been found that, for workpieces 6 of different specifications, the distance T 'from the detected edge ab to the center point of the workpiece 6 is known (the specification of the workpiece 6 is different, the value of T' is different), and the center point of the workpiece 6 is known from the inspection process of the workpiece 6On the right side of the detected edge of the workpiece, the coordinate value X of the center point on the X axis_T′Then determining; when the workpiece 6 is at the ideal position of the next station, the distance from the central point to the Y axis in the X axis direction is P', and the coordinate value on the X axis is X_P′The numerical control transverse linear motion unit 3 acts to make the central point of the workpiece 6 move by a distance | x_P′-x_T′Completing the transverse centering of the workpiece 6; extreme case x_T′And x_P′And if the two positions are the same, the numerical control transverse linear motion unit does not perform transverse alignment on the workpiece 6.

(24) And (3) longitudinal alignment process:

after the transverse alignment process is completed, starting longitudinal alignment, and conveying the workpiece 6 to the next station: the servo motor of the numerical control longitudinal linear motion unit 4 is started, so that the workpiece 6 moves towards the Y-axis in the forward direction (upwards in the figure), the auxiliary edge is set as the edge which is firstly detected by the workpiece 6 when the numerical control longitudinal linear motion unit 4 moves in the longitudinal alignment process, in the embodiment, the auxiliary edge is set as the adjacent edge bc of the detected edge ab, when a point B of the second sensor 122 detects a point on the adjacent edge bc of the workpiece 6, a signal is sent, the control system is triggered to start the rotation angle counting of the servo motor of the numerical control longitudinal linear motion unit 4, when the counting value is equal to the rotation angle setting value of the servo motor, the servo motor of the numerical control longitudinal linear motion unit 4 stops, the workpiece 6 is sent to the lower position, the longitudinal position of the workpiece 6 is aligned at the same time, the process is equivalent to that after the adjacent edge bc of the workpiece 6 is detected at the point B of the second sensor 122, the numerical control longitudinal linear motion unit 4, so that the workpiece 6 reaches the next station desired position (see fig. 3 f).

One setting mode of the fixed distance D is as follows: when the workpiece 6 is at the ideal position of the next station, the distance from the intersection point of the adjacent side bc and the Y axis to the point B is as follows: each workpiece 6 sent to the next station has the same distance from bc edge to point B. The longitudinal alignment process and the workpiece feeding action process are combined, so that the process time is saved.

If the workpiece 6 is in a shape with a center line or a symmetrical middle point, the workpiece 6 can also be used for centering the center line and the middle point in the above way, only workpieces 6 with different specifications have different centering stroke settings, and can be correspondingly set in a program, wherein the setting mode is similar to the transverse centering of the center line of the workpiece 6: when the numerical control longitudinal linear motion unit 4 moves upwards in the figure, after a point B of the second sensor 122 measures a point bc on an adjacent side of the workpiece 6, because the distance C from the point B of the second sensor 122 to the ideal center line of the workpiece 6 is known, and the distance V from the side bc of the workpiece to the center line of the workpiece 6 is also known (the workpieces 6 with different specifications have different V values), the numerical control longitudinal linear motion unit 4 walks by a fixed distance D of | C-V |, longitudinal alignment of the workpiece 6 is completed, and the workpiece 6 is simultaneously sent to the next station.

Secondly, the steps of detecting position deviation and aligning the workpiece 6 with the arc or circular detected edge are as follows:

(1) the inspection process comprises the following steps:

fig. 5a shows the initial position of the table, in which the workpiece 6 is circular, in which the workpiece 6 is mounted on the workpiece support tray 7 and fixed, and then triggers the inspection: the numerically controlled vertical linear motion unit 4 is not moved, and the numerically controlled horizontal linear motion unit 3 is moved in the reverse direction (leftward in the drawing) toward the X axis to move the workpiece support tray 7 and the workpiece 6 thereon to the sensor sensing area, and a point a' on the detected side of the workpiece is detected at a point a of the first sensor 121 (see fig. 5b), at which point Y is detected₁Distance x of axis from Y axis_ANamely A' point and O₁The X axial distance of the points; thereafter, the numerically controlled lateral rectilinear motion unit 3 continues to move the workpiece support tray 7, and detects another point B' on the detected side of the workpiece at point B of the second sensor 122 (see FIG. 5c), and also at this time Y₁Distance x of axis from Y axis_BI.e. the B' point and the O point on the detected edge of the workpiece₁X axial distance of points.

Initial position Y of workpiece 6 during loading₁Distance between axis and Y-axis (i.e. O point to O point)₁The distance of the point) is determined, so that the control system can be based on when a second point on the detected edge of the workpiece is detected, O₁Judging O point and O point according to the displacement value of the point₁Positional relationship of points (whether O point is on the left or O₁Point at left side), and according to the judged result, the numerical control transverse linear motion unit 3 continues to move the workpiece support disk 7 until O₁Coincident with point O, Y₁The axis coinciding with the Y axisWhen the examination is finished, the coordinates of the points A ' and B ' on the X-axis of the YOX coordinate system are determined, and the coordinates of the points A and B on the Y-axis of the YOX coordinate system are known and are (0, L/2) and (0, -L/2), respectively, so that the coordinates of the points A ' are (X)_AL/2), the coordinates of the B' point are (x)_BL/2) and the radius R of the arc of the workpiece 6 is also known, so that the following system of equations is obtained:

the inspection process can know that the circle center is on the right side of two points A 'and B' on the circular arc, namely: selecting one of the two solutions of x with smaller absolute value, and using the solution of x to obtain the corresponding value of y, the control system calculates the coordinate O of the position of the workpiece 6 at the moment with the center of the circle in the YOX coordinate system_gj(x，y)。

(2) The alignment process comprises the following steps:

FIG. 5d shows the coordinates (0, W) of the ideal center of the workpiece 6 in the YOX coordinate system, and the coordinates O of the actual center of the workpiece 6 in the YOX coordinate system calculated by the control system_gj(x, y), the center of the circle of the workpiece 6 is sent to an ideal center position (0, W) through the actions of the numerical control transverse linear motion unit 3 and the numerical control longitudinal linear motion unit 4, namely: the center coordinates of the workpiece 6 are superposed with the coordinates of the ideal position of the workpiece 6, so that the workpiece 6 with the arc or circle detected edge is aligned, and the method specifically comprises the following steps:

the transverse moving distance of the numerical control transverse linear motion unit 3 is | x |, so that the center O of the circle of the workpiece 6 is ensured_gjThe X coordinate in the YOX coordinate system is 0 (consistent with the horizontal coordinate of the ideal position of the circle center), and the horizontal position deviation of the workpiece 6 is aligned;

the longitudinal moving distance of the numerical control longitudinal linear motion unit 4 is | W-y |, so that the center O of the circle of the workpiece 6 is_gjThe Y coordinate in the YOX coordinate system is W (the Y coordinate is consistent with the vertical coordinate of the ideal position of the circle center), and the longitudinal position of the workpiece 6 is deviatedThe difference is aligned and the work piece 6 is delivered to the next station.

As can be seen from the inspection and alignment processes of the circular arc-shaped and circular workpieces 6, the worktable for only the circular arc-shaped and circular workpieces 6 may not have the turning mechanism 2.

Thirdly, the steps of detecting position deviation and aligning the workpiece 6 with the oval detected edge are as follows:

(1) the inspection process comprises the following steps:

FIG. 6a shows the initial position of the table, where the workpiece 6 is oval, and Y is set₂The shaft being through O₁The axis of the point parallel to the major axis of the ellipse; in this position the workpiece 6 is mounted on the workpiece support plate 7 and secured, and the inspection is then triggered:

the numerically controlled vertical linear motion unit 4 is not moved, and the numerically controlled horizontal linear motion unit 3 is moved in the reverse direction (leftward in the drawing) toward the X axis to move the workpiece support tray 7 and the workpiece 6 thereon to the sensor sensing region, and a point a1 (see fig. 6b) on the detected side of the workpiece is detected at point a of the first sensor 121, at which point Y is detected₁Distance x of axis from Y axis_A1I.e. A1 point and O point on the detected edge of the workpiece₁The X axial distance of the points; thereafter, the numerically controlled lateral rectilinear motion unit 3 continues to move the workpiece support tray 7, and detects a second point B1 (see fig. 6c) on the detected side of the workpiece at point B of the second sensor 122, and likewise, at this time Y₁Distance x of axis from Y axis_B1I.e. B1 point and O point on the detected edge of the workpiece₁The X axial distance of the points; thereafter, the numerically controlled lateral linear motion unit 3 continues to move the workpiece support tray 7 to sense a third point a2 (see fig. 6d) on the detected side of the workpiece at point a of the first sensor 121, and likewise, at this time Y₁Distance x of axis from Y axis_A2I.e. the B' point and the O point on the detected edge of the workpiece₁The X axial distance of the points; finally, the numerically controlled transverse linear motion unit 3 continues to move the workpiece support tray 7, sensing the fourth point B2 on the detected side of the workpiece at point B of the second sensor 122, and Y at this time, too₁Distance x of axis from Y axis_B2I.e. B2 point and O point on the detected edge of the workpiece₁The X axial distance of the points; after the detection of 4 points A1, A2, B1 and B2 is completed, the transverse linear motion unit 3 moves when O₁Point and point O are heavyAfter closing, the servo motor of the lateral linear motion unit 3 is stopped, Y₁The axes coincide with the Y axis, and the state at the end of the examination is shown in FIG. 6f, where the X-axis coordinates of the points A1, B1, A2 and B2 in the YOX coordinate system are determined, and the Y-axis coordinates of the points A and B are known and are (0, L/2), (0, -L/2), respectively, and the A1 point coordinates are (X, L/2)_A1L/2), the coordinate of point B1 is (x)_B1-L/2), the coordinate of point A2 is (x)_A2L/2), the coordinate of point B2 is (x)_B2-L/2); the semi-major axis a, the semi-minor axis b and the focal length of the detected edge of the workpiece are known, and the focal point F is set₁Has the coordinates of (x)₁，y₁) Focal point F₂Has the coordinates of (x)₂，y₂) Then, the following system of equations can be obtained:

find F₁And F₂After the coordinates are obtained, the equation of the ellipse major axis in the YOX coordinate system can be obtained, the included angle beta between the ellipse major axis and the Y axis can be further obtained, the angle is the deflection angle of the ellipse major axis, and the focus F can be obtained₁Distance to point O R:

the control system sends the values of the rotation direction and the rotation angle beta to a servo controller of the numerical control rotation mechanism 2, the motor of the numerical control rotation mechanism 2 rotates according to the instruction, and the Y axis₁Axis, Y₂The axes are coincident, the ellipse major axis is parallel to the Y axis, the deflection angle of the ellipse major axis is eliminated, and the transverse position deviation and the longitudinal position deviation of the ellipse are to be calculated. As shown in FIG. 6g, the two-dot chain line ellipse in the figure indicates the position of the workpiece 6 before deflection angle alignment, the solid line ellipse indicates the position of the workpiece 6 after deflection angle alignment, and F₁' is the focus F of the ellipse₁The new position when the deflection angle alignment is completed can be obtained by the geometric relationship of FIG. 6g, the distance H from the ellipse major axis to the Y axis and the ellipse focus F₁ ^＇Distance to point O, M:

so far, the transverse position deviation and the longitudinal position deviation of the ellipse are completely determined, and then the transverse position deviation and the longitudinal position deviation of the ellipse are aligned in a similar way to the alignment of a circular (arc-shaped) workpiece 6, namely, the focus of the workpiece 6 is sent to an ideal position by the numerical control transverse linear motion unit 3 and the numerical control longitudinal linear motion unit 4, and the specific steps are as follows:

the numerical control transverse linear motion unit 3 transversely moves for a distance of | H |, so that the coordinates of two focuses of the workpiece 6 in a YOX coordinate system are 0, and the transverse position deviation of the workpiece 6 is aligned;

when the workpiece 6 is arranged at the ideal position of the next station, the focus F of the ellipse₁The distance from the X axis is U, the longitudinal moving distance of the numerical control longitudinal linear motion unit 4 is | U-M |, two focuses of the workpiece 6 are overlapped with the focus of an ideal position, the longitudinal position deviation of the workpiece 6 is aligned, and meanwhile, the workpiece 6 is sent to the next station.

Similarly, when the deflection direction of the workpiece 6 is as shown in fig. 6h, similarly to the case of the workpiece 6 whose detected edge is a straight line, the point B of the second sensor 122 detects the point B ' on the elliptical outline of the workpiece 6 first, and then the point a ' of the first sensor 121 detects the other point a ' on the elliptical outline of the workpiece 6, in this case, the calculation principle of each deviation value of the ellipse of the workpiece 6 is the same as the above-mentioned case where the point a of the first sensor 121 detects the point on the elliptical outline of the workpiece 6 first, and the control system can judge the direction of the angular deviation of the major axis of the ellipse of the workpiece 6 only according to the sequence in which the two sensors detect the workpiece 6, that is: when the first sensor 121 detects a point on the outline of the ellipse first and the deflection angle is found, the numerical control rotating mechanism 2 rotates clockwise to eliminate the deflection angle of the workpiece 6, and when the second sensor 122 detects a point on the outline of the ellipse first and the deflection angle is found, the numerical control rotating mechanism rotates counterclockwise to eliminate the deflection angle of the workpiece 6.

In addition, it should be noted that the specific embodiments described in the present specification may be different in the components, the shapes of the components, the names of the components, and the like, and the above description is only an example of the structure of the present invention. All the equivalent changes or simple changes made according to the structure, characteristics and principle of the utility model are included in the protection scope of the utility model. Various modifications, additions and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.

Claims (9)

1. A workbench for detecting position deviation and alignment of a workpiece by using a sensor is characterized in that: the device comprises a sensor component, a numerical control transverse linear motion unit, a numerical control longitudinal linear motion unit, a machine base and a workpiece supporting disc; the numerical control longitudinal linear motion unit is fixedly arranged on the base; the numerical control transverse linear motion unit is arranged on the numerical control longitudinal linear motion unit, and the motion directions of the numerical control longitudinal linear motion unit and the numerical control transverse linear motion unit are mutually vertical; the workpiece supporting disc is arranged on the numerical control transverse linear motion unit; the sensor assembly comprises a sensor bracket and two sensors, and the sensors are arranged on the sensor bracket; the sensing points of the two sensors are positioned on the central axis of the numerical control longitudinal linear motion unit and are arranged in a front-back mode.

2. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 1, wherein: the workbench is also provided with a numerical control swing mechanism, the numerical control swing mechanism is arranged on the numerical control transverse linear motion unit, the workpiece supporting disc is connected with the numerical control swing mechanism, and the numerical control swing mechanism drives the workpiece supporting disc to rotate.

3. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 1, wherein: the workpiece supporting disc is a vacuum chuck, an electromagnetic chuck or a pressing plate type workpiece supporting disc.

4. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 1, wherein: the sensor is a photoelectric sensor, an optical fiber sensor, a laser sensor, an ultrasonic sensor or a proximity switch.

5. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 1, wherein: the executing mechanisms of the numerical control transverse linear motion unit and the numerical control longitudinal linear motion unit are a screw nut mechanism with a position sensing function, a gear rack mechanism, a chain transmission mechanism, a belt transmission mechanism, a cam guide rod mechanism, a connecting rod mechanism, an oil cylinder, a linear motor or a linear motion module.

6. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 2, wherein: the device also comprises a control system, and the sensor, the numerical control slewing mechanism, the numerical control transverse linear motion unit and the numerical control longitudinal linear motion unit are electrically connected with the control system.

7. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 2, wherein: the numerical control swing mechanism comprises a motor and a motor bracket; the motor support is arranged on the numerical control transverse linear motion unit, the motor is vertically and upwards arranged on the motor support, and the workpiece supporting disc is arranged on a motor output shaft of the motor.

8. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 7, wherein: the motor is a brake motor, a stepping motor or a servo motor with a rotary encoder.

9. The stage for detecting positional deviation and alignment of a workpiece using a sensor according to claim 6, wherein: the control system is an industrial personal computer or a PLC.

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