CN112629472A - Measuring and calculating method of turbine disc tenon tooth inclination angle measuring and calculating tool - Google Patents

Abstract

The invention relates to a measuring and calculating method of a turbine disc tenon tooth inclination angle measuring and calculating tool, wherein the turbine disc tenon tooth inclination angle measuring and calculating tool comprises a profile gauge, a turbine disc clamp and a clamp limiting stop lever, the profile gauge comprises a profile gauge base and a movable profile gauge measuring needle, the clamp limiting stop lever is fixedly arranged on the profile gauge base, a clamping groove for clamping a turbine disc is arranged above the turbine disc clamp, the bottom end of the turbine disc clamp is in sliding fit with the clamp limiting stop lever, when the turbine disc is used, the turbine disc is vertically arranged in the clamping groove, so that the central axis of the turbine disc to be measured is parallel to the clamp limiting stop lever, the profile gauge measuring needle and the clamp limiting stop lever are vertically arranged, a measuring head of the profile gauge measuring needle can extend into a tenon tooth groove to be contacted with the arc top surface of a tenon tooth, and the precision of a measuring block and the profile gauge is very high.

Description

Measuring and calculating method of turbine disc tenon tooth inclination angle measuring and calculating tool

Technical Field

The invention relates to the technical field of turbine disc measurement, in particular to a tool and a method for measuring and calculating a turbine disc tenon tooth inclination angle.

Background

The turbine disc for the aircraft engine is used as an important part of the aircraft engine, the outer circumference of the turbine disc 1 generally consists of nearly hundreds of groups of tenon tooth grooves with the same shape, the common connection mode is a fir-tree shape, each tenon tooth groove 11 consists of a plurality of tenon teeth 12 with different sizes, each tenon tooth 12 is obliquely arranged along the axial direction, the inclination angle between the front end of the tenon tooth and the rear end of the tenon tooth in the axial direction is generally 10-20 degrees, namely the height of the front end of the tenon tooth in the radial direction is lower than that of the rear end of the tenon tooth in the radial direction, the tenon tooth groove is obtained by processing a tenon tooth broach, the section of a single tenon tooth 12 is approximately trapezoidal, the processing mainly comprises the processing of a front inclined plane 13, a rear inclined plane 14 and an arc top plane 15, and the tenon tooth 12 is obliquely arranged and is fastened and compacted after assembly, so the dimensional accuracy of the inclination angle between the front end of the tenon tooth and the rear end of the tenon tooth plays a key role in subsequent assembly, and the inclination angle accuracy detection of the tenon tooth on Accordingly.

In the chinese patent application with chinese patent application publication No. CN106643596A, a switching device and a measurement system for turbine disc mortise measurement are disclosed, by designing an adapter tenon matched with a mortise on a turbine disc, the measured mortise position degree is switched to the switching device easy to measure, i.e. whether the turbine disc mortise position degree is qualified is indirectly measured by measuring the position degree of the switching device relative to the turbine disc, the above design structure is complex and is indirect measurement, and the precision is low; the design of the tool and the method for measuring and calculating the inclination angle of the tenon tooth of the turbine disc, which have the advantages of simple structure and higher precision, is a technical problem which needs to be solved urgently by a person skilled in the art.

Disclosure of Invention

The invention aims to solve the technical problem of providing a tool and a method for measuring and calculating the inclination angle of the tenon tooth of a turbine disc, which are simple in structure and high in precision.

In order to solve the technical problem, the turbine disc tenon tooth inclination angle measuring and calculating tool comprises a contourgraph, a turbine disc clamp and a clamp limiting stop lever, wherein the contourgraph comprises a contourgraph base and a movable contourgraph measuring pin, the clamp limiting stop lever is fixedly arranged on the contourgraph base, a clamping groove for clamping a turbine disc is arranged above the turbine disc clamp, the bottom end of the turbine disc clamp is in sliding fit with the clamp limiting stop lever, the turbine disc is vertically arranged in the clamping groove when the tool is used, the central axis of the turbine disc to be measured is parallel to the clamp limiting stop lever, and a measuring head of the contourgraph measuring pin can extend into a tenon tooth groove to be contacted with the arc-shaped top surface of a tenon tooth.

Further, turbine dish anchor clamps include the anchor clamps base, set up on the anchor clamps base that a left side props, well vertical brace and right vertical brace, the right side props immediately and forms the centre gripping groove between propping with well vertical brace, a left side prop with well vertical brace forms the inner groovy between propping, the width of centre gripping groove and the axial height looks adaptation of turbine dish to make the turbine dish can stand in the centre gripping inslot.

Further, turbine dish anchor clamps still include clamping screw, well vertical stay, left vertical stay on set up with clamping screw looks adaptation's screw to it is tight fixed by clamping screw top when putting the centre gripping inslot in turbine dish.

Further, the fixture limiting stop lever comprises a longitudinal stop lever and a transverse stop lever which are integrally arranged, so that the fixture limiting stop lever is L-shaped, and one side of the fixture base is abutted to the longitudinal stop lever, so that the turbine disc fixture can move along the longitudinal stop lever.

Further, the turbine disc tenon tooth inclination angle measuring and calculating tool further comprises a gauge block used for limiting axial displacement of the turbine disc clamp, the size of the gauge block does not exceed the axial height of the turbine disc, and the gauge block can be arranged between the clamp base and the transverse stop rod.

The measuring and calculating method of the turbine disc tenon tooth inclination angle measuring and calculating tool comprises the following steps:

A. the turbine disc is erected in the clamping groove, and the clamping screw is screwed down to limit the turbine disc.

B. The turbine disk clamp is placed on the contourgraph base, so that one side of the clamp base abuts against the longitudinal stop rod, the tail end of the clamp base abuts against the transverse stop rod, and the central axis of the turbine disk is parallel to the longitudinal stop rod.

C. And starting the contourgraph to enable a measuring needle of the contourgraph to be vertical to the longitudinal stop rod, moving the measuring needle of the contourgraph to the extent that the measuring needle of the contourgraph extends into the tenon tooth groove along the direction of the transverse stop rod, enabling a measuring head at the front end of the measuring needle of the contourgraph to be in contact with the ARC top surface at the front end of the tenon tooth to be measured, keeping the axial position of the measuring needle of the contourgraph in the turbine disc unchanged, and moving the measuring needle of the contourgraph along the radial direction to enable the measuring head to move on the ARC top surface so as to.

D. Keeping the axial position of the measuring needle of the contourgraph in the turbine disc unchanged, moving the turbine disc clamp along the longitudinal stop rod to enable the gauge block to be arranged between the rear end of the turbine disc clamp and the transverse stop rod, enabling the turbine disc clamp to be tightly attached to the gauge block and the transverse stop rod, namely enabling the axial moving distance of the turbine disc to be the size of the gauge block, and enabling the rear end of the tenon tooth to be measured to be arranged at the measuring needle of the contourgraph.

E. And moving the measuring needle of the contourgraph along the direction of the transverse stop rod to enable the measuring needle of the contourgraph to extend into the tenon tooth groove, enabling the measuring head at the front end of the measuring needle of the contourgraph to be in contact with the ARC top surface at the rear end of the tenon tooth to be measured, keeping the axial position of the measuring needle of the contourgraph in the turbine disc unchanged, and moving the measuring needle of the contourgraph along the direction of the transverse stop rod to enable the measuring head to move on the ARC top surface so as to measure the profile ARC2 of the ARC.

F. A high point P1 of the ARC-shaped top surface contour ARC1 at the front end of the tenon tooth and a high point P2 of the ARC-shaped top surface contour ARC2 at the rear end of the tenon tooth are selected by a contourgraph, a difference L1 between the P1 and the P2 is calculated, the difference L1 is a height difference between the front end of the tenon tooth and the rear end of the tenon tooth in the vertical direction, the size L2 of the gauge block is a length difference between the front end of the tenon tooth and the rear end of the tenon tooth in the axial direction, and the inclination angle between the front end of the tenon tooth and the rear end of the tenon tooth can be calculated according to arctangent functions of L1 and L2.

The invention has the technical effects that: (1) compared with the prior art, the turbine disc tenon tooth inclination angle measuring and calculating tool has the advantages that the function of accurately drawing a curved surface profile can be realized by using a profiler, the defect that a measuring needle of the profiler cannot move in multiple dimensions simultaneously is overcome by moving a turbine disc clamp, so that the measuring head can accurately measure the arc-shaped top surface profile at the front end of the tenon tooth and the arc-shaped top surface profile at the rear end of the tenon tooth, the characteristic of a curve high point can be found out by using the profiler, the height difference between the front end of the tenon tooth and the rear end of the tenon tooth in the vertical direction is calculated, the measuring block is used as the length difference between the front end of the tenon tooth and the rear end of the tenon tooth in the axial direction, the inclination angle between the front end of the tenon tooth and the rear end of the tenon tooth can be calculated by combining the measuring block and the profiler, and the accuracy; (2) the turbine disc clamp is matched with the longitudinal stop lever, so that the turbine disc can slide along the longitudinal stop lever when moving, the movement is convenient, the operation is easy, and the measurement efficiency can be improved.

Drawings

The invention is described in further detail below with reference to the drawings of the specification:

FIG. 1 is a schematic perspective view of a turbine disk tenon tooth inclination angle measuring and calculating tool for measuring the front end of a tenon tooth;

FIG. 2 is a front view of FIG. 1;

FIG. 3 is a top view of FIG. 1;

FIG. 4 is an enlarged view of a portion of area A of FIG. 2;

FIG. 5 is a schematic perspective view of a turbine disk tenon inclination angle measuring and calculating tool for measuring the rear end of a tenon;

FIG. 6 is a top view of FIG. 5;

FIG. 7 is a schematic view of the profile ARC1 of the leading end of the tooth and ARC2 of the trailing end of the tooth as measured by a profilometer.

In the figure: the measuring device comprises a turbine disc 1, a tenon tooth groove 11, a tenon tooth 12, a front inclined plane 13, a rear inclined plane 14, an arc top surface 15, a contourgraph base 2, a turbine disc clamp 3, a left vertical support 31, a middle vertical support 32, a right vertical support 33, an inner groove 34, a clamping groove 35, a clamp base 36, a clamping screw rod 4, a contourgraph measuring rod 5, a contourgraph measuring needle 51, a measuring head 52, a clamp limiting stop rod 6, a longitudinal stop rod 61, a transverse stop rod 62 and a measuring block 7.

Detailed Description

Example 1

The turbine disc tenon tooth inclination angle measuring tool comprises a contourgraph, a turbine disc clamp 3 and a clamp limit stop lever 6, wherein the contourgraph comprises a contourgraph base 2 and a movable contourgraph measuring pin 51, the tail end of the contourgraph measuring pin 51 is driven by a contourgraph measuring rod 5 to move, a measuring head 52 is arranged at the front end of the contourgraph measuring pin 51, the MarSuXC 2 type contourgraph of German Mark company can be adopted, the resolution of the measuring pin can reach 0.25um/175mm measuring rod, the system resolution is 0.04um, the distance of a contour point is 0.07um, and the requirement of high-precision measurement can be met.

The fixed spacing pin 6 that sets up a anchor clamps on contourgraph base 2, this spacing pin 6 of anchor clamps include vertical pin 61 and the horizontal pin 62 that integrated into one piece and mutually perpendicular set up to make anchor clamps spacing pin 6 be the L type, use the extending direction of vertical pin 61 to be the Y axle, horizontal pin extending direction 62 be the X axle, the direction of rise and fall of contourgraph survey needle 51 is the Z axle.

The turbine disc clamp 3 comprises a clamping screw rod 4 and a clamp base 36, a left vertical support 31, a middle vertical support 32 and a right vertical support 33 are arranged on the clamp base 36, a clamping groove 35 is formed between the right vertical support 33 and the middle vertical support 32, an inner groove 34 is formed between the left vertical support 31 and the middle vertical support 32, so that the whole turbine disc clamp 3 is in a Chinese character 'shan' -shape, the width of the clamping groove 35 is matched with the axial height of a turbine disc 1 to be tested, so that the turbine disc 1 can stand in the clamping groove 35, and screw holes matched with the clamping screw rod 4 are arranged on the middle vertical support 32 and the left vertical support 31, so that the turbine disc 1 is tightly pressed and fixed by the clamping screw rod 4 when being placed in the clamping groove 35.

In order to directly measure the axial movement length of the turbine disc clamp 3, the turbine disc tenon tooth inclination angle measuring and calculating tool further comprises a gauge block 7 used for limiting the axial displacement of the turbine disc clamp 3, the dimension of the gauge block 7 does not exceed the axial height of the turbine disc 1, for example, the axial height of the turbine disc 1 to be measured is 20mm, the design requirement of the tenon tooth inclination angle is 10.0 degrees +/-0.05 degrees, therefore, the selected gauge blocks 7 are four equal gauge blocks with the dimension of 15mm, and after the turbine disc clamp 3 moves, the gauge block 7 can be arranged between the clamp base 36 and the transverse stop rod 62, so that the movement distance of the turbine disc clamp 3 can be conveniently calibrated.

When the turbine disc 1 is used, the turbine disc 1 is erected in the clamping groove 35, so that the central axis of the turbine disc 1 to be measured is parallel to the longitudinal stop rod 61 of the fixture limiting stop rod 6, and the contourgraph measuring needle 51 and the longitudinal stop rod 61 of the fixture limiting stop rod 6 are vertically arranged, so that the measuring head 52 of the contourgraph measuring needle 51 can extend into the tenon tooth groove 11 to be contacted with the arc-shaped top surface 15 of the tenon tooth 12.

Example 2

The measuring and calculating method of the turbine disc tenon tooth inclination angle measuring and calculating tool comprises the following steps:

A. the turbine disc 1 is erected in the clamping groove 35, the clamping screw 4 is screwed down to limit the turbine disc 1, so that the turbine disc 1 is erected in the clamping groove 35, and the side walls of the middle vertical support 32 and the right vertical support 33 are in contact with two ends of the turbine disc 1.

B. The turbine disk clamp 3 is placed on the profiler base 2 such that one side of the clamp base 36 abuts against the longitudinal stop 61 and the trailing end of the clamp base 36 abuts against the transverse stop 62, with the central axis of the turbine disk 1 parallel to the longitudinal stop 61.

C. The contourgraph is started to enable the contourgraph measuring needle 51 to be perpendicular to the longitudinal stop rod 61, the contourgraph measuring needle 51 is moved until the contourgraph measuring needle 51 extends into the tenon slot 11 along the direction of the transverse stop rod 62 (namely, the X-axis direction), the measuring head 52 at the front end of the contourgraph measuring needle 51 is contacted with the ARC top surface 15 at the front end of the tenon tooth 12 to be measured (namely, the front end in the Y-axis direction), the position of the contourgraph measuring needle 51 in the axial direction (namely, the Y-axis direction) of the turbine disc 1 is kept unchanged, and the contourgraph measuring needle 51 is moved along the direction of the transverse stop rod 62 (namely, the X-axis direction) to enable the measuring head 52 to move on the ARC top surface 15 so as to measure the profile ARC1 of the ARC top surface 15.

D. Keeping the position of the profiler measuring needle 51 in the axial direction (i.e. the Y-axis direction) of the turbine disc 1 unchanged, moving the turbine disc clamp 3 along the longitudinal stop rod 61 direction (i.e. the Y-axis direction) so that the gauge block 7 is placed between the front end of the turbine disc clamp 3 and the transverse stop rod 62, and enabling the turbine disc clamp 3 to be tightly attached to the gauge block 7 and the gauge block 7 to be tightly attached to the transverse stop rod 62, namely, the axial moving distance of the turbine disc 3 is the size of the gauge block 7, and at this time, the rear end of the tenon tooth 12 to be measured is placed at the profiler measuring needle 51.

E. The contourgraph needle 51 is moved in the direction of the transverse stop lever 62 (i.e. the X-axis direction) so that the contourgraph needle 51 extends into the tenon slot 11, the measuring head 52 at the front end of the contourgraph needle 51 is contacted with the ARC top surface 15 at the rear end of the tenon tooth 11 to be measured, the position of the contourgraph needle 51 in the axial direction of the turbine disc 1 is kept unchanged, and the contourgraph needle 51 is moved in the direction of the transverse stop lever 62 so that the measuring head 52 moves on the ARC top surface 15, so as to measure the profile ARC2 of the ARC top surface 15 at the rear end of the tenon tooth 12, as shown in fig. 5 to 6.

F. A high point P1 of the ARC-shaped top surface contour ARC1 at the front end of the tenon tooth and a high point P2 of the ARC-shaped top surface contour ARC2 at the rear end of the tenon tooth are selected by a profiler, a difference L1 between the P1 and the P2 is calculated, the difference L1 is a height difference between the front end of the tenon tooth and the rear end of the tenon tooth in the vertical direction, a size L2 of the gauge block 7 is a length difference between the front end of the tenon tooth and the rear end of the tenon tooth in the axial direction, and an inclination angle between the front end of the tenon tooth and the rear end of the tenon tooth can be calculated according to arctan arctangent function of L1 and L2, as shown.

The data measured twice can be directly opened, combined and displayed on the drawing software of the contourgraph, the command for searching the high points in the drawing software is utilized to find out the high points P1 and P2 of the ARCs ARC1 and ARC2, the distance difference between the high points P1 and P2 is calculated to be 2.65789mm, the value is divided by the measuring range of the gauge block to be 15mm, then the angle is measured to be 10.04809 degrees by an inverse tangent function, the angle is the inclination angle of the tenon tooth of the turbine disc, and the design requirement of the inclination angle of the tenon tooth is 10.0 degrees +/-0.05 degrees, so that the inclination angle of the tenon tooth meets the design requirement.

It should be understood that the above examples are only for clearly illustrating the present invention and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And such obvious variations or modifications which fall within the spirit of the invention are intended to be covered by the scope of the present invention.

Claims (1)

1. A method for measuring and calculating a turbine disc tenon tooth inclination angle measuring and calculating tool is characterized by comprising the following steps:

A. the turbine disc is erected in the clamping groove, and the clamping screw is screwed down to limit the turbine disc;

B. placing the turbine disc clamp on the contourgraph base, enabling one side of a clamp base to abut against the longitudinal stop lever, enabling the tail end of the clamp base to abut against the transverse stop lever, and enabling the central axis of the turbine disc to be parallel to the longitudinal stop lever;

C. starting the contourgraph to enable a measuring needle of the contourgraph to be vertical to the longitudinal stop rod, moving the measuring needle of the contourgraph to the extent that the measuring needle of the contourgraph extends into the tenon tooth groove along the direction of the transverse stop rod, enabling a measuring head at the front end of the measuring needle of the contourgraph to be in contact with the ARC-shaped top surface at the front end of the tenon tooth to be measured, keeping the axial position of the measuring needle of the contourgraph unchanged in the turbine disc, and moving the measuring needle of the contourgraph along the radial direction to enable the measuring head to move on the ARC-shaped top surface;

D. keeping the position of a measuring pin of the contourgraph in the axial direction of the turbine disc unchanged, moving the turbine disc clamp along the longitudinal stop rod to enable the gauge block to be arranged between the rear end of the turbine disc clamp and the transverse stop rod, enabling the turbine disc clamp to be tightly attached to the gauge block, enabling the gauge block to be tightly attached to the transverse stop rod, namely enabling the moving distance of the turbine disc in the axial direction to be the size of the gauge block, and enabling the rear end of the tenon tooth to be measured to be arranged at the measuring pin of the contourgraph at the moment;

E. moving a measuring needle of the contourgraph along the direction of the transverse stop rod to enable the measuring needle of the contourgraph to extend into the tenon tooth groove, enabling a measuring head at the front end of the measuring needle of the contourgraph to be in contact with the ARC-shaped top surface at the rear end of the tenon tooth to be measured, keeping the axial position of the measuring needle of the contourgraph unchanged in the turbine disc, and moving the measuring needle of the contourgraph along the direction of the transverse stop rod to enable the measuring head to move on the ARC-shaped top surface to measure the profile ARC2 of the;

F. a high point P1 of the ARC-shaped top surface contour ARC1 at the front end of the tenon tooth and a high point P2 of the ARC-shaped top surface contour ARC2 at the rear end of the tenon tooth are selected by a contourgraph, a difference L1 between the P1 and the P2 is calculated, the difference L1 is a height difference between the front end of the tenon tooth and the rear end of the tenon tooth in the vertical direction, the size L2 of the gauge block is a length difference between the front end of the tenon tooth and the rear end of the tenon tooth in the axial direction, and the inclination angle between the front end of the tenon tooth and the rear end of the tenon tooth can be calculated according to arctangent functions of L1 and L2.

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