CN108534647B

CN108534647B - Detection tool for detecting part errors and application method thereof

Info

Publication number: CN108534647B
Application number: CN201810519820.XA
Authority: CN
Inventors: 崔士捷
Original assignee: Huayu Pierboge Pump Technology Co ltd
Current assignee: Huayu Pierboge Pump Technology Co ltd
Priority date: 2018-05-28
Filing date: 2018-05-28
Publication date: 2024-05-17
Anticipated expiration: 2038-05-28
Also published as: CN108534647A

Abstract

When the detection tool for detecting the part errors is used, the calibration part is firstly arranged on the bottom plate, then the detection frame is moved and contacted with the baffle plate, then the detection head is regulated to be contacted with the detected surface on the calibration part, and then the calibration part is taken off from the bottom plate after the dial indicator is zeroed; thus, a measurement reference based on the detected surface of the calibration part mounted on the base plate can be determined; after the checking part is taken down, the part to be detected is installed on the bottom plate, the detection frame is moved to the position propped against the baffle plate, the contact state of the detection head and the detected surface of the part to be detected is adjusted, the measurement value is read from the dial indicator, and the manufacturing error of the detected surface of the part to be detected can be obtained according to the measurement value.

Description

Detection tool for detecting part errors and application method thereof

Technical Field

The invention relates to a detection tool for detecting part errors and a use method thereof.

Background

In the manufacturing industry, it is often necessary to detect dimensional factors such as a distance error between a hole and a surface on a part, a flatness error and a position error of the surface. As shown in fig. 1 and 2, the structure of the part 1 to be detected is a relatively common structure, the part 1 to be detected has the same structural characteristics as the machined locating surface 3, the first locating hole 4, the second locating hole 5 and the detected surface 6 on the calibration part 2, the detected surface 6 is perpendicular to the machined locating surface 3, and the first locating hole 4 and the second locating hole 5 are perpendicular to the machined locating surface 3; because of the machining errors, certain errors exist in the distances between the first positioning hole 4, the second positioning hole 5 and the detected surface 6 for different parts, and certain errors exist in the flatness and the position degree of the detected surface 6, so that the errors need to be detected to judge whether the sizes of the parts are qualified. However, there is no device capable of rapidly detecting these dimensional errors, and the detection means in the prior art are complex and have low detection efficiency.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, an object of the present invention is to provide a detection tool for detecting errors of parts and a method for using the same, which can detect errors of sizes of parts conveniently.

In order to achieve the above purpose, the invention provides a detection tool for detecting errors of parts, wherein the parts to be detected comprise a processing locating surface, a first locating hole and a second locating hole which are perpendicular to the processing locating surface, and the parts to be detected also comprise a detected surface which is perpendicular to the processing locating surface; the detection tool comprises a bottom plate provided with a detection positioning surface, and a first positioning pin and a second positioning pin which are perpendicular to the detection positioning surface are arranged on the bottom plate; the bottom plate is also provided with a baffle plate perpendicular to the detection positioning surface and a linear guide rail perpendicular to the baffle plate; the linear guide rail is connected with a detection frame in a sliding manner, a plurality of detection heads are connected to the detection frame, and the detection heads are connected with the dial indicator through a conversion mechanism.

Preferably, the bottom plate is provided with a first quick clamping mechanism and a second quick clamping mechanism, and the first quick clamping mechanism and the second quick clamping mechanism are used for pressing the part to be detected on the bottom plate.

Preferably, the bottom plate is further provided with a pushing mechanism, and the pushing mechanism is used for pressing the detection frame towards the baffle plate.

Preferably, the detection frame comprises a frame plate parallel to the baffle plate, two ends of the frame plate are connected with a first sliding block and a second sliding block, the linear guide rail comprises a first half guide rail and a second half guide rail which are parallel to each other, and the first sliding block and the second sliding block are respectively and slidably connected to the first half guide rail and the second half guide rail.

More preferably, the frame plate is provided with 4 detection heads.

More preferably, the conversion mechanism comprises a connecting block connected to the frame plate, a rotary crank arm is connected to the connecting block, the rotary crank arm comprises a first connecting arm and a second connecting arm, a detection column of the dial indicator is propped against the first connecting arm, and the detection head is propped against the second connecting arm.

Further, the first connecting arm is perpendicular to the second connecting arm, the detection column of the dial indicator extends in the vertical direction, and the detection head extends in the horizontal direction.

Further, the first and second connecting arms are equal in length.

Correspondingly, the invention also provides a use method of the detection tool for detecting the part errors, which adopts the technical scheme or any one of the preferable technical schemes for operation, and comprises the following steps:

1) Matching the machining locating surface of the calibration part with the detection locating surface on the bottom plate, and matching the first locating hole and the second locating hole on the calibration part with the first locating pin and the second locating pin on the bottom plate respectively;

2) Sliding the detection frame along the linear guide rail, enabling the frame to be detected to be in contact with the baffle, adjusting the detection head to be in contact with a detected surface on the calibration part, and taking down the calibration part from the bottom plate after zeroing the dial indicator;

3) Matching the processing locating surface of the part to be detected with the detection locating surface on the bottom plate, and respectively matching the first locating hole and the second locating hole on the part to be detected with the first locating pin and the second locating pin on the bottom plate;

4) And sliding the detection frame along the linear guide rail, enabling the to-be-detected frame to be in contact with the baffle, then adjusting the detection head to be in contact with a detected surface on the part to be detected, and reading and recording the dial indicator.

As described above, the detection tool for detecting the part error and the use method thereof have the following beneficial effects: in the detection tool for detecting the part errors, the detection frame is provided with the plurality of detection heads, and the detection frame can slide along the linear guide rail and enables the detection heads to be in contact with the detected surface on the part to be detected; when the detection tool for detecting the part errors is used, the calibration part is firstly arranged on the bottom plate, then the detection frame is moved and contacted with the baffle, then the detection head is regulated to be contacted with the detected surface on the calibration part, and then the calibration part is taken off from the bottom plate after the dial indicator is zeroed; thus, a measurement reference based on the detected surface of the calibration part mounted on the base plate can be determined; after the checking part is taken down, the part to be detected is installed on the bottom plate, the detection frame is moved to the position propped against the baffle plate, the contact state of the detection head and the detected surface of the part to be detected is adjusted, the measurement value is read from the dial indicator, and the manufacturing error of the detected surface of the part to be detected can be obtained according to the measurement value. Therefore, the detection tool for detecting the part errors and the use method thereof can conveniently detect the size errors of the parts, and are simple in structure, convenient to use and capable of improving detection efficiency.

Drawings

FIG. 1 is a schematic perspective view of a calibration part;

FIG. 2 is a schematic perspective view of another angle of the calibration part;

FIG. 3 is a top view of a part to be inspected with an inspection tool for inspecting part errors according to the present invention;

FIG. 4 is a left side view of the inspection tool of FIG. 3 for inspecting part errors;

Fig. 5 is a schematic diagram showing the cross-sectional structures of the conversion mechanism, the inspection rack, the stopper, the part to be inspected, and the like from the view point of fig. 3.

Description of element reference numerals

1. Part to be detected

2. Calibrating parts

3. Processing locating surface

4. First positioning hole

5. Second positioning hole

6. Surface to be inspected

7. Detection positioning surface

8. Bottom plate

9. First locating pin

10. Second locating pin

11. Baffle plate

12. Linear guide rail

13. Detection rack

14. Detection head

15. Conversion mechanism

16. Dial gauge

17. First quick clamping mechanism

18. Second quick clamping mechanism

19. Pressing mechanism

20. Frame plate

21. First slider

22. Second slider

23. First half guide rail

24. Second half guide rail

25. Connecting block

26. Rotary crank arm

27. First connecting arm

28. Second connecting arm

29. Detection column

30. Sleeve barrel

Detailed Description

Further advantages and effects of the present invention will become apparent to those skilled in the art from the disclosure of the present invention, which is described by the following specific examples.

It should be understood that the structures, proportions, sizes, etc. shown in the drawings are for illustration purposes only and should not be construed as limiting the invention to the extent that it can be practiced, since modifications, changes in the proportions, or otherwise, used in the practice of the invention, are not intended to be critical to the essential characteristics of the invention, but are intended to fall within the spirit and scope of the invention. Also, the terms such as "upper," "lower," "left," "right," "middle," and "a" and the like recited in the present specification are merely for descriptive purposes and are not intended to limit the scope of the invention, but are intended to provide relative positional changes or modifications without materially altering the technical context in which the invention may be practiced.

As shown in fig. 3 to 5, the present invention provides a detection tool for detecting errors of parts, wherein a part 1 to be detected includes a processing locating surface 3, a first locating hole 4 and a second locating hole 5 perpendicular to the processing locating surface 3, and the part 1 to be detected also has a detected surface 6 perpendicular to the processing locating surface 3; the detection tool comprises a bottom plate 8 provided with a detection positioning surface 7, and a first positioning pin 9 and a second positioning pin 10 which are perpendicular to the detection positioning surface 7 are arranged on the bottom plate 8; the bottom plate 8 is also provided with a baffle 11 vertical to the detection positioning surface 7 and a linear guide rail 12 vertical to the baffle 11; the linear guide rail 12 is slidably connected with a detection frame 13, a plurality of detection heads 14 are connected to the detection frame 13, and the detection heads 14 are connected with a dial indicator 16 through a conversion mechanism 15. Preferably, the first positioning pins 9 are cylindrical positioning pins and the second positioning pins 10 are diamond positioning pins.

In a detection tool for detecting errors of parts according to the present invention, referring to fig. 3 to 5, a plurality of detection heads 14 are provided on a detection frame 13, and the detection frame 13 can slide along a linear guide rail 12 and make the detection heads 14 contact a detected surface 6 on a part 1 to be detected; when the detection tool for detecting the part errors is used, the calibration part 2 is firstly arranged on the bottom plate 8, then the detection frame 13 is moved and is contacted with the baffle 11, then the detection head 14 is regulated to be contacted with the detected surface 6 on the calibration part 2, and then the calibration part 2 is taken off from the bottom plate 8 after the dial indicator 16 is calibrated; thus, a measurement reference with respect to the inspected surface 6 of the calibration part 2 mounted on the base plate 8 can be determined; after the calibration part 2 is taken down, the part 1 to be detected is mounted on the bottom plate 8, the detection frame 13 is moved to a position propped against the baffle plate 11, the contact state of the detection head 14 and the detected surface 6 of the part 1 to be detected is adjusted, the measurement value is read from the dial indicator 16, and the manufacturing error of the detected surface 6 of the part 1 to be detected can be obtained according to the measurement value. Therefore, the detection tool for detecting the part errors and the use method thereof can conveniently detect the size errors of the parts, and are simple in structure, convenient to use and capable of improving detection efficiency.

As a preferred embodiment, as shown in fig. 3, the base plate 8 is provided with a first quick clamping mechanism 17 and a second quick clamping mechanism 18, and the first quick clamping mechanism 17 and the second quick clamping mechanism 18 are used for pressing the part 1 to be detected on the base plate 8. In this way, the part 1 to be inspected is firmly fixed on the base plate 8 and cannot move, so that the result obtained by the inspection is more accurate.

In the part 1 to be inspected and the calibration part 2, the nominal dimensions of the first positioning hole 4 and the second positioning hole 5 from the surface to be inspected are fixed, for example, please refer to fig. 5, the nominal dimension between the first positioning hole 4 and the surface to be inspected is L, while the actual dimension between the first positioning hole 4 on the part 1 to be inspected and the surface to be inspected is L ', the error between L and L' is small, and the error can be calculated according to the data measured by the dial gauge 16. When the detection tool for detecting the part errors is used for measuring the size errors of the part 1 to be detected, firstly, the checking part 2 is arranged on the bottom plate 8, the dial indicators 16 are calibrated by the aid of the surface to be detected of the checking part 2, the dial indicators 16 are calibrated to be zero, the detection frame 13 is made to be close to the check block, then the detection heads 14 of the dial indicators 16 are made to be in contact with the surface to be detected of the checking part 2, and then the pointers of the dial indicators 16 are calibrated to be zero, and at the moment, the plane overlapped with the surface 6 to be detected of the checking part 2 is taken as a reference detection surface. When the part 1 to be detected is detected later, after the part 1 to be detected is positioned and mounted on the bottom plate 8, a small error exists between the detected surface 6 on the part to be detected and the reference detection surface, the detection frame 13 is moved to a position close to the baffle 11, the detection heads 14 of the dial indicators 16 are adjusted to be in contact with the detected surface 6 of the part 1 to be detected, and the error between the detected surface 6 on the part to be detected and the reference detection surface can be obtained through the reading of the dial indicators 16. In order to reliably abut the detection frame 13 against the baffle plate 11, it is preferable that, as shown in fig. 3 and 5, a pressing mechanism 19 is further provided on the bottom plate 8, and the pressing mechanism 19 is used for pressing the detection frame 13 against the baffle plate 11. The detection frame 13 comprises a frame plate 20 parallel to the baffle 11, two ends of the frame plate 20 are connected with a first sliding block 21 and a second sliding block 22, the linear guide rail 12 comprises a first half guide rail 23 and a second half guide rail 24 which are parallel to each other, and the first sliding block 21 and the second sliding block 22 are respectively connected to the first half guide rail 23 and the second half guide rail 24 in a sliding manner. When the detection frame 13 is abutted against the baffle 11, the frame plate 20 is abutted against the baffle 11. As shown in fig. 3, the frame plate 20 is provided with 4 detecting heads 14, and the 4 detecting heads 14 are aligned to each position on the detected surface 6 of the part 1 to be detected as uniformly as possible according to the space layout.

In the detection tool for detecting the part errors, the dial indicator 16 and the detection head 14 are connected through the conversion mechanism 15, as shown in fig. 5, the detection head 14 is installed in the sleeve 30 arranged on the frame plate 20, the detection head 14 can move axially, the detection head 14 transmits the dimension errors on the surface to be detected to the dial indicator 16 through the conversion mechanism 15, and therefore the numerical values read from the dial indicator 16 are the dimension errors obtained through detection. The conversion mechanism 15 comprises a connecting block 25 connected to the frame plate 20, a rotary crank arm 26 is connected to the connecting block 25, the rotary crank arm 26 comprises a first connecting arm 27 and a second connecting arm 28, a detection column 29 of the dial indicator 16 abuts against the first connecting arm 27, and the detection head 14 abuts against the second connecting arm 28. Thus, the movement of the detecting head 14 drives the rotary crank arm 26 to rotate, and the rotary crank arm 26 converts the displacement of the detecting head 14 in the horizontal direction into the displacement of the detecting column 29 of the dial indicator 16 in the vertical direction. More preferably, the first connecting arm 27 is perpendicular to the second connecting arm 28, the detecting column 29 of the dial indicator 16 extends in the vertical direction, the detecting head 14 extends in the horizontal direction, and the angle between the detecting head 14 and the first connecting arm 27 is equal to the angle between the detecting column 29 and the second connecting arm 28; when the detection column 29 is perpendicular to the first connection arm 27, the detection head 14 is perpendicular to the second connection arm 28. Further, the first connecting arm 27 and the second connecting arm 28 have equal lengths.

1) Matching the machining positioning surface 3 of the calibration part 2 with the detection positioning surface 7 on the bottom plate 8, and matching the first positioning hole 4 and the second positioning hole 5 on the calibration part 2 with the first positioning pin 9 and the second positioning pin 10 on the bottom plate 8 respectively;

2) The detection frame 13 slides along the linear guide rail 12, the frame 13 to be detected is contacted with the baffle 11, then the detection head 14 is regulated to be contacted with the detected surface 6 on the checking part 2, and the checking part 2 is taken off from the bottom plate 8 after the dial indicator 16 is zeroed;

3) The processing locating surface 3 of the part 1 to be detected is matched with the detection locating surface 7 on the bottom plate 8, and the first locating hole 4 and the second locating hole 5 on the part 1 to be detected are respectively matched with the first locating pin 9 and the second locating pin 10 on the bottom plate 8;

4) The detection frame 13 slides along the linear guide rail 12, the to-be-detected frame 13 is contacted with the baffle 11, then the detection head 14 is adjusted to be contacted with the detected surface 6 on the part 1 to be detected, and the reading of the dial indicator 16 is read and recorded.

Preferably, the base plate 8 is further provided with a first quick clamping mechanism 17 and a second quick clamping mechanism 18, the first quick clamping mechanism 17 and the second quick clamping mechanism 18 are used for pressing the part 1 to be detected on the base plate 8, the base plate 8 is further provided with a pushing mechanism 19, and the pushing mechanism 19 is used for pressing the detection frame 13 towards the baffle plate 11. The pushing mechanism 19 is capable of moving back and forth in a direction parallel to the linear guide 12.

More preferably, in said step 1), the collation part 2 is pressed onto the base plate 8 by means of a first quick clamping mechanism 17 and a second quick clamping mechanism 18; in step 2), the detection rack 13 is pressed against the shutter 11 by the pressing mechanism 19.

More preferably, in said step 3), the part 1 to be inspected is pressed against the bottom plate 8 by means of a first rapid clamping mechanism 17 and a second rapid clamping mechanism 18; in step 4), the detection rack 13 is pressed against the shutter 11 by the pressing mechanism 19.

According to the theory of tolerance and fit, we can calculate and evaluate the errors of the distance error between the first positioning hole 4 and the detected surface 6, the distance error between the second positioning hole 5 and the detected surface 6, the flatness and the position of the detected surface 6, and the like on the part 1 to be detected according to the read reading of the dial indicator 16.

Based on the technical scheme of the embodiment, the detection tool for detecting the part errors and the use method thereof can conveniently detect the size errors of the parts, are simple in structure and convenient to use, and can improve the detection efficiency.

In summary, the present invention effectively overcomes the disadvantages of the prior art and has high industrial utility value.

The above embodiments are merely illustrative of the principles of the present invention and its effectiveness, and are not intended to limit the invention. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the invention. Accordingly, it is intended that all equivalent modifications and variations of the invention be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims

1. The detection tool for detecting the part errors comprises a part to be detected (1) and a detection device, wherein the part to be detected (1) comprises a processing locating surface (3), a first locating hole (4) and a second locating hole (5) which are perpendicular to the processing locating surface (3), and the part to be detected (1) is also provided with a detected surface (6) which is perpendicular to the processing locating surface (3); the detection tool is characterized by comprising a bottom plate (8) provided with a detection positioning surface (7), wherein a first positioning pin (9) and a second positioning pin (10) which are perpendicular to the detection positioning surface (7) are arranged on the bottom plate (8); the bottom plate (8) is also provided with a baffle (11) perpendicular to the detection positioning surface (7) and a linear guide rail (12) perpendicular to the baffle (11); the linear guide rail (12) is connected with a detection frame (13) in a sliding manner, the linear guide rail (12) comprises a first half guide rail (23) and a second half guide rail (24) which are parallel to each other, the detection frame (13) comprises a frame plate (20) which is parallel to the baffle plate (11), two ends of the frame plate (20) are connected with a first sliding block (21) and a second sliding block (22), the first sliding block (21) and the second sliding block (22) are respectively connected with the first half guide rail (23) and the second half guide rail (24) in a sliding manner, 4 detection heads (14) are arranged on the frame plate (20), the detection heads (14) are connected with a dial indicator (16) through a conversion mechanism (15), the conversion mechanism (15) comprises a connecting block (25) which is connected with the frame plate (20), a rotary crank arm (26) is connected with the connecting block (25), the rotary crank arm (26) comprises a first connecting arm (27) and a second connecting arm (28), a detection column (29) of the dial indicator (16) is abutted against the first connecting arm (27), the detection heads (14) are connected with the second connecting arm (28) in a vertical direction along the first connecting column (28), the detection head (14) is movable in a horizontal direction.

2. The inspection tool for detecting part errors according to claim 1, wherein: the base plate (8) is provided with a first quick clamping mechanism (17) and a second quick clamping mechanism (18), and the first quick clamping mechanism (17) and the second quick clamping mechanism (18) are used for pressing the part (1) to be detected on the base plate (8).

3. The inspection tool for detecting part errors according to claim 1, wherein: the bottom plate (8) is also provided with a pushing mechanism (19), and the pushing mechanism (19) is used for pressing the detection frame (13) towards the baffle plate (11).

4. The inspection tool for detecting part errors according to claim 1, wherein: the first connecting arm (27) and the second connecting arm (28) are equal in length.

5. A method of using the tool for detecting part errors according to any one of claims 1 to 4, comprising the steps of:

Matching a machining positioning surface (3) of the calibration part (2) with a detection positioning surface (7) on the bottom plate (8), and matching a first positioning hole (4) and a second positioning hole (5) on the calibration part (2) with a first positioning pin (9) and a second positioning pin (10) on the bottom plate (8) respectively;

sliding the detection frame (13) along the linear guide rail (12) and enabling the frame (13) to be detected to be in contact with the baffle plate (11), then adjusting the detection head (14) to be in contact with the detected surface (6) on the correction part (2), and taking down the correction part (2) from the bottom plate (8) after zeroing the dial indicator (16);

the processing locating surface (3) of the part to be detected (1) is matched with the detection locating surface (7) on the bottom plate (8), and the first locating hole (4) and the second locating hole (5) on the part to be detected (1) are respectively matched with the first locating pin (9) and the second locating pin (10) on the bottom plate (8);

The detection frame (13) slides along the linear guide rail (12) and enables the frame (13) to be detected to be in contact with the baffle plate (11), then the detection head (14) is adjusted to be in contact with the detected surface (6) on the part (1) to be detected, and the reading of the dial indicator (16) is read and recorded.