METHOD AND APPARATUS FOR INJECTING WATER RESTRAINT LAYER OF LASER SHOCK PROCESSING BLADE

Abstract

A method and an apparatus for injecting a water restraint layer of a laser shock processing blade, including a laser device distance measuring instrument platform bracket distance measuring instrument controller I, and water tap transition joint, signal wires, hose, and water tank. A standard curved section corresponding to two probe points I, and a point to be processed, on a vertical section along a laser beam direction on the blade is used for approximately replacing an actual curved section on the blade, so that a water flow flows into the blade from a middle point of the standard curved section approximately as a middle point of the actual curved section, and the long side of a flat nozzle is parallel to the tangent plane of the point to be processed of the blade through the controller according to feedback information of the distance measuring instrument.

Description

BACKGROUND OF INVENTION

1. Field of the Invention

The presented invention relates to a method and an apparatus to spray water confinement layer on the surface of workpiece during laser shock peening process, and forms a homogeneous water layer on the peening region. This method is suitable to form water layer on low curvature surface (curvature radius<50).

2. Background Art

Laser shock peening (LSP) is an advanced surface strengthening technology. With high power, high pressure, super speed and super strain rate, LSP technology has unmatched advantage over conventional methods. It can greatly improve the durability of metal, prevent the initiation of cracks, extend the life expectancy of workpieces and reduce the cost of maintenance. Since the beginning of the 21st century, USA has applied LSP technology to strength or reproduce turbine blades in fighter F101, F119 and F414.

In order to achieve the strengthen effect of LSP; a confinement layer should be applied on the peening surface. The thickness, material (Component and property) of the confinement layer directly affects the peening effect. Up to now, materials reported in literatures are: K9 glass, organic glass, silica gel, synthetic resin and water, etc. The glass like confinement layer has a great effect on upgrading shock power, but can only suit on the flat surface. And it also has disadvantages such as frangibility and hard to clean. Silica gel and synthetic resin have a poor binding force with the target surface, and can hardly be reused. The advantages of the water confinement layer are: cheap, clean, recycle and can easily be applied to curved surface; the flowing water can also remove the solid particles produced by plasma Explosion. In LSP industry, the water is the most commonly used material for confinement layer.

The typical industrial application of LSP is the laser shock peening process of the turbine blisk. For the blades have curved surface, during the process, a programmable multi-axis workbench is used to adjust the motion and rotation of the blisk, to keep the laser beam perpendicular to the tangent plane of the peening point. Currently, the existing water confinement applying apparatus has a fixed water tap; the angle and the position of the water jet cannot be adjusted. During the peening process, if the water flow velocity is too big, a gap may form between the water layer and the concave surface of the blade. This phenomenon should be evaded, for laser will directly ablate the blade surface and cause undesired damage. If the water layer is too thick, it will negatively affect the LSP process. In order to achieve a perfect strengthen effect, only controlling the motion and position of the blisk is not enough, the direction of the water jet should also be optimized during the peening process.

CONTENTS OF INVENTION

The presented invention has been made in order to solve the above problems in the prior part. A method and an apparatus solve these problems.

A method to spray water confinement layer: in the plane of incident laser beam, take three points (probe point I, probe point II and peening point) from the blade surface; Then build a theoretical curve trough the coordinates of this points; Take this curve as the outline of the blade, adjust the position of the tap and make the angle between water jet and the tangent plane of peening point 10°-15°; let the water flow from the midpoint of theoretical curve into the work plane, so a stable and homogeneous water confinement layer can be formed in the peening region.

An apparatus for spray water confinement layer comprising: diastimeter platform 2, holder 14, diastimeter 3, controller I 5, controller II 8, tap 4, Transition joint 7, signal line I 10, signal line II 11, signal line III 28, signal line IV 29, flexible pipe 12, and water tank 6; Two detection heads (detection head I 16 and detection head II 17) are installed on the diastimeter 3, the distance between them is adjustable (10-20 mm). The vector from detection head I 16 to detection head II 17 is perpendicular to the bottom plane of diastimeter 3. The output end of the diastimeter 3 is connected to the input end of the controller I 5. The controller I 5 is the general control, it controls the motion of five-axis table 9, controller II 8 and tap 4; The signal line III 5 connect the input end of the five-axis table 9 and the output end of the controller I 5; diastimeter platform 2 is located between the laser device 1 and the five-axis table 9; diastimeter 3 is fixed on the diastimeter platform 2 through the holder so the laser beam can get through the gap between the diastimeter 3 and diastimeter platform 2 without interference; signal line I 10 connected the output end of diastimeter 3 with the input end of controller I 5; to prevent the interference with laser beam 15, the controller I 5 is located beyond the five-axis table 9 and its output end is connected with the input end of tap 4; controller II 8 is fitted on the transition joint 7, signal line IV 29 connected the input end of controller II 8 with the output end of the controller I 5; tap 4 is located beyond the five-axis table 9 which is 10-20 mm higher than the detection head I 16, the tap 4 is connected with flexible pipe 12 through the transition joint 7; the water tank 6 is located beyond tap 4 and joint with transition joint 7.

The tap 4 contains a outer casing 26 and a flat nozzle, the sectional dimension of the nozzle is 1 mm×2 mm, and it can rotate around the axis of the outer casing 26; there are taper pipe threads at the two ends of the transition joint 7 and tap 4 and flexible pipe 12 is connected to the different end of the transition joint 7. Controller II 8 is set between the flexible pipe 12 and the outer casing 26 of tap 4, which is used to control the rotation of nozzle and the flux, pressure, velocity of the water jet. The flexible pipe 12 is consisted by 15-30 small taper pipes, the angle between two adjacent taper pipe axes is below 30°, so the flexible pipe 12 can be set as any angle and position. The controller II 8 is controlled by the controller I 5, it can adjust the position of tap 4 and the rotation of nozzle 27 due to different working condition. Before LSP according to the feed back information from the diastimeter 3, the controller I adjust the position of nozzle 27 and makes its long side parallel to the tangent plane of the peening point 22 on the blade 13, and adjusts the angle between water jet and the tangent plane of peening point to 10°-15°, makes sure that a uniform water confinement layer can be formed in the peening region.

The specific steps for using this apparatus:

(1) Use holder 14 to fix diastimeter 3 on the diastimeter platform 2, make sure that the vector between detection head I 16 and detection head II 17 is perpendicular to the datum plane 23, and parallel to the laser beam 15; while the vertical distance between detection head II 17 and peening point 22 is 10-20 mm, the horizontal distance between detection head II 17 and peening point 22 is 20-30 mm; adjust the position of detection head I 16 to make the vertical distance to the peening point 22 is D2 (D2=D1×2).

(2) Clamp the blade 13 on the five-axis table 9, control the motion of the five-axis table 9 make the peening point is on the focal point of laser beam 15 and make sure that the tangent plane of peening point 22 is coincide with the work plane 25.

(3) Get two points, whose vertical distance from the peening point 22 is D2 and D1 respectively, and measure their distance from the work plane 25 (L1 and L2), then input L1, L2, D1, D2 to the controller I 5; through the program in the controller I 5, take the incident laser beam 15 as horizontal axis, the vertical direction as vertical axis, and peening point 22 as original point build a coordinate system, then input coordinates (L1, D1) and (L2, D2); according to the input coordinates, the controller I 5 works out the rotation angle and the displacement of tap 4. For tan θ=D2/L2, where θ is the angle between water jet and the tangent plane of peening point; the abscissa of the water jet spraying point is (L2−2L1)/2*Cos(θ)*Cos(θ)+L1 and the ordinate of the water jet spraying point is (L2−2L1)/2*Cos(θ)*Sin(θ)+D1. According to these data the controller I 5 can control the motion or rotation of the tap 4, and through controller II 8 adjust the rotation of nozzle 27 make its long side parallel to the tangent plane of the peening point 22 on the blade 13, and the angle between water jet and the tangent plane of peening point between 10°-15°, to form a homogeneous water confinement layer.

(4) Through controller II 8, controller I 5 adjusts the flux and speed of the water jet. Adjust the thickness of water confinement layer on the peening region between 1-3 mm to guarantee the stability of water confinement layer and keep it contact with the blade surface.

Positive Effects:

(1) Enhance the LSP quality and effect. The tap can adjust its position due to different spatial location of the blade to form a stable and homogeneous water confinement layer.

(2) Simplified the complex information of the blade surface, easy for Programming and automation. The real surface in the laser incident plane is simplified to micro theoretical curve, which is figured out by take three points from the blade surface.

(3) The water jet enters the surface from the mid-point of the theoretical curve. This method prevents the formation of turbulent flow at the peening point.

(4) The design of the flat nozzle can easily adjust parallel to the tangent plane of the peening point, and from a homogeneous water confinement layer; mean while keep the angle between water jet and the tangent plane of peening point between 100 o-15 o can improve stability of LSP, prevent the formation of gap between the water confinement layer and blade surface, or local block in the concave surface of the blade.

(5) The controller II, which is set between the flexible pipe and the outer casing of tap, can directly control the flux, pressure, and velocity of the water jet nd the rotation of the nozzle.

(6) The Transition joint can strengthen the joint strength between the flexible and tap, and act as a buffer when water flow change from roundness to rectangle, make the apparatus can bear higher water pressure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is the schematic diagram of the water confinement layer spraying apparatus.

FIG. 2 is the schematic diagram of how water jet is sprayed.

FIG. 3 is the tap chart.

FIG. 4 is the nozzle chart.

FIG. 5 is the connection of tap, Transition joint, controller II and flexible pipe.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 is the Schematic diagram of the apparatus. It contains diastimeter platform 2, holder 14, diastimeter 3, controller I 5, controller II 8, tap 4, Transition joint 7, signal line I 10, signal line II 11, signal line III 28, signal line IV 29, flexible pipe 12, and water tank 6. The signal line III 5 connects the input end of the five-axis table 9 and the output end of the controller I 5; diastimeter platform 2 is located between the laser device 1 and the five-axis table 9; diastimeter 3 is mounted on the diastimeter platform 2 through the holder (the laser beam can get through the gap between the diastimeter 3 and diastimeter platform 2 with on interference); signal line I 10 connects the output end of diastimeter 3 with the input end of controller I 5; to prevent the interference with laser beam 15, the controller I 5 is located beyond the five-axis table 9 and it's output end is connected with the input end of tap 4; controller II 8 is fitted on the transition joint 7, signal line IV 29 connected the input end of controller II 8 with the output end of the controller I 5; tap 4 is located beyond the beyond the five-axis table 9 witch 10-20 mm higher than the detection head I 16, the tap 4 is connected with flexible pipe 12 through the Transition joint 7; the water tank 6 is located beyond tap 4 and joint with Transition joint 7.

EMBODIMENTS

(1) Use holder 14 to fix diastimeter 3 on the diastimeter platform 2, make sure that the vector between detection head I 16 and detection head II 17 is perpendicular to the datum plane 23, and parallel to the laser beam 15; while the vertical distance between detection head II 17 and peening point 22 is 10-20 mm, the horizontal distance between detection head II 17 and peening point 22 is 20-30 mm; adjust the position of detection head I 16 make the vertical distance to the peening point 22 is D2 (D2=D1×2).

(2) Clamp the blade 13 on the five-axis table 9, control the motion of the five-axis table 9 make the peening point is on the focal point of laser beam 15 and make sure that the tangent plane of peening point 22 is coincide with the work plane 25.

(3) Get two points, which their vertical distance form the peening point 22 is D2 and D1 respectively, and measure their distance to the work plane 25 (L1 and L2), then input L1, L2 to the controller I 5; through the program in the controller I 5, take the incident laser beam 15 as horizontal axis, the vertical direction as vertical axis, and peening point 22 as original point build a coordinate system, then input coordinates (L1, D1) and (L2, D2); according to the input coordinates, the controller I 5 works out the rotation angle and the displacement of tap 4, so it can control the motion or rotation of the tap 4, while the controller II 8 controls the rotation of nozzle 27, makes the long side of the nozzle 27 is parallel to the tangent plane of the peening point 22 on the blade 13, the angle between water jet and the tangent plane of peening point is 10°-15°;

(4) Through controller II 8, controller I 5 adjusts the flux and the speed of the water jet, keeps the thickness of water confinement layer on the peening region is 1-3 mm, and guarantees the stability of water confinement layer and keeps it contacting with the blade surface.

Claims

1-5. (canceled)

6. A water confinement layer spraying apparatus comprising: a diastimeter platform, a holder, a diastimeter, a controller I, a controller II, a tap, a transition joint, a signal line I, a signal line II, a signal line III, a signal line IV, a flexible pipe, and a water tank; two detection heads (detection head I and detection head II) installed on the diastimeter, the distance between them being adjustable; an output end of the diastimeter being connected to an input end of the controller I; the controller I being the general control for controlling the motion of a five-axis table, controller II and tap; the signal line III connecting an input end of the five-axis table and an output end of the controller I; the diastimeter platform being located between the laser device and the five-axis table; the diastimeter being fixed on the diastimeter platform through the holder so the laser beam can get through the gap between the diastimeter and diastimeter platform without interference; signal line I being connected to the output end of the diastimeter with the input end of controller I; the controller I being located beyond the five-axis table and its output end being connected with the input end of tap; controller II being fitted on the transition joint, signal line IV being connected the input end of controller II with the output end of the controller I; the tap being located beyond the five-axis table which is 10-20 mm higher than the detection head I, the tap being connected with flexible pipe through the transition joint; and the water tank being located beyond tap and joint with transition joint; wherein the controller II controls the motion and rotation of the tap.

7. The water confinement layer spraying apparatus according to claim 6, wherein the tap contains a outer casing and a flat nozzle, a sectional dimension of the flat nozzle is 1 mm×2 mm, the flat nozzle being rotatable around the axis of the outer casing, wherein there are taper pipe threads at the both ends of the transition joint and the tap and the flexible pipe being connected to the different end of the transition joint, the controller II being set between the flexible pipe and the outer casing of tap, which is used to control the rotation of nozzle and the flux, pressure, velocity of the water jet, the flexible pipe comprising 15-30 small taper pipes; the angle between two adjacent taper pipe axes is below 30°.

8. The water confinement layer spraying apparatus according to claim 7, wherein the sectional dimension of the flat nozzle is 1 mm×2 mm.

9. A method for spraying a water confinement layer: in the plane of incident laser beam, comprising taking three points (probe point I, probe point II and peening point) from the blade surface; building a theoretical curve trough the coordinates of said points; taking the curve as the outline of the blade, adjusting the position of the tap and making the angle between water jet and the tangent plane of peening point 10°-15°; letting the water flow from the midpoint of theoretical curve into the work plane, so a stable and homogeneous water confinement layer is formed in the peening region.

10. The method to spray water confinement layer according to claim 9, further comprising clamping the blade on the five-axis table, controlling the motion of the five-axis table to make the peening point on the focal point of laser beam and making sure that the tangent plane of peening point coincides with the work plane; taking two points, in which their vertical distance from the peening point is D2 and D1 respectively, and measuring their distance to the work plane (L1 and L2), then input L1, L2 to the controller I; through the program in the controller I, taking the incident laser beam as horizontal axis, the vertical direction as vertical axis, and peening point as original point build a coordinate system, and inputting coordinates (L1, D1) and (L2, D2); according to the input coordinates, the controller I works out the rotation angle and the displacement of tap, so it can control the motion or rotation of the tap, while the controller II controls the rotation of nozzle, making the long side of the nozzle parallel to the tangent plane of the peening point on the blade, the angle between water jet and the tangent plane of peening point is 10°-15°;through controller II, wherein controller I adjusts the flux and the speed of the water jet, keeps the thickness of water confinement layer on the peening region is 1-3 mm, and guarantees the stability of water confinement layer and keeps it contacting with the blade surface.

11. The method to spray water confinement layer according to claim 10, wherein the location and angle of the tap: for tan θ=D2/L2, where θ is the angle between water jet and the tangent plane of peening point; the abscissa of the water jet spraying point is (L2−2L1)/2*Cos(θ)*Cos(θ)+L1 and the ordinate of the water jet spraying point is (L2−2L1)/2*Cos(θ)*Sin(θ)+D1.