CN117685921A - Automatic aperture detection adjusting device for automobile mold production and detection method thereof - Google Patents

Abstract

The utility model relates to the technical field of aperture detection devices, in particular to an automatic aperture detection adjusting device for automobile mold production and a detection method thereof, comprising the following steps: the handheld part is provided with a controller at the top end; the detection part is rotationally connected to the bottom end of the handheld part; the contact assembly is arranged on the surface of the detection part and is used for detecting the aperture; the shielding assembly comprises a shielding plate, wherein the shielding plate is used for extruding and shielding a measuring point contact of the contact assembly, when the detecting part is inserted into a hole to be detected, the shielding plate moves vertically upwards to enable the measuring point contact to stably enter the hole to be detected.

Description

Automatic aperture detection adjusting device for automobile mold production and detection method thereof

Technical Field

The utility model relates to the field of aperture detection devices, in particular to an automatic aperture detection adjusting device for automobile die production and a detection method thereof.

Background

The gauge is a simple tool for controlling various sizes of products, such as aperture, space size and the like, of industrial production enterprises, improves production efficiency and control quality, and is suitable for mass production of products, such as automobile parts, so as to replace professional measuring tools.

The prior art discloses a part of patent documents related to aperture detection, the utility model patent with publication number of CN203518911U discloses an aperture measuring device, which comprises a barrel, a pair of radial holes are symmetrically arranged on the circumferential wall of the barrel, a contact is slidingly matched in each radial hole, one end of the contact extends into an axial hole of the barrel, the other end of the contact penetrates out of an orifice of the radial hole positioned on the circumferential wall of the barrel, an inclined plane is arranged at the end part of the contact extending into the axial hole of the barrel, a conical spring is sleeved on the contact, one end of the spring is connected with the contact, the other end of the spring is fixed with the barrel, a sleeve is arranged in the axial hole of the barrel, one end of the sleeve extends out of the axial hole of the barrel and then is connected with a dial gauge, a measuring rod of the dial gauge extends into the sleeve, and the end part of the measuring rod is conical.

In the prior art, when the measuring tool is used for detection, the measuring tool is inserted into a hole to be detected of a workpiece, the measuring tool contacts the hole wall through the measuring point contact, and then the measuring tool is rotated to enable the measuring point contact to rotate in the hole for measurement;

under normal state, the measuring point contact is in the convex state under the promotion of internal spring, can directly strike with the hole outer wall when detecting, very fragile contact, in the in-process of daily operation, the operating personnel need be careful the wing with the measuring tool slow insert wait to detect downthehole, avoid causing strong striking damage to the measuring point contact, and then lead to operating personnel to be difficult to carry out quick detection.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides an automatic aperture detection adjusting device for automobile die production and a detection method thereof.

To achieve the above object, in a first aspect, the present utility model provides an aperture detection automatic adjustment device for automobile mold production, comprising:

the handheld part is provided with a controller at the top end;

the detection part is rotationally connected to the bottom end of the handheld part;

the contact assembly is arranged on the surface of the detection part and is used for detecting the aperture;

the shielding assembly comprises a shielding plate, the shielding plate is used for extruding and shielding the measuring point contact of the contact assembly, and when the detecting part is inserted into the hole to be detected, the shielding plate moves vertically upwards to enable the measuring point contact to stably enter the hole to be detected;

it should be noted that, under the normal state, the measuring point contact is in a protruding state under the pushing of the internal spring, and can directly collide with the outer wall of the hole during detection, so that the contact is extremely easy to damage, and in the daily operation process, an operator needs to carefully insert the measuring tool slowly into the hole to be detected by the wing, so that the strong collision damage to the measuring point contact is avoided, and the operator is difficult to quickly detect;

it should be further noted that, in the detection principle of the measuring tool in the prior art, the aperture of the hole to be detected is obtained by measuring the horizontal displacement of the measuring point contact, which is the prior art, and will not be repeated here;

before detection, the shielding component can squeeze and shield the measuring point contact, so that the contact is contracted in the detection part, and is difficult to be impacted and damaged by external objects, thereby being beneficial to protecting the measuring point contact in an unused state;

because the surface laminating of shielding plate and detection portion, insert the detection portion and wait to detect the inside in-process of hole, shielding plate can shelter from the protection to the measurement station contact all the time to the measurement station contact is in the in-process of waiting to detect the hole, is in the shrink state, and can not take place the striking with the pore wall, and then through setting up the shielding plate, can effectively protect the measurement station contact, operating personnel can insert fast at the detection in-process, and then is favorable to improving detection efficiency.

Preferably, the shielding assembly comprises:

the top parts of the support blocks are jointly fixed with a mounting ring, and the mounting ring is fixed on the bottom surface of the handheld part;

the mounting groove is formed in the supporting block close to the measuring point contact, and the shielding plate is arranged in the mounting groove;

the guide grooves are formed in the outer walls of the two sides of the mounting groove, guide rods are inserted into the guide grooves, and the guide rods are fixed on the shielding plates;

the elastic pushing assembly is arranged between the shielding plate and the inner top surface of the mounting groove and is used for pushing the shielding plate downwards.

In a second aspect, the present utility model provides a method for detecting an aperture for producing an automobile mold, wherein a pressure sensor is fixed on an inner top surface of one of the mounting cylinders, the method comprising the steps of:

the controller acquires first request information, and the first request information is generated after the pressure sensor detects that the pressure value rises to a first preset value;

the controller generates first control information according to the first request information, wherein the first control information is used for controlling the extension of the electric cylinder;

the controller sends first control information to the electric cylinder.

Preferably, the detection method further comprises the steps of:

the controller acquires second request information, and the second request information is generated after the pressure value detected by the pressure sensor is reduced to a second preset value;

the controller generates second control information according to the second request information, wherein the second control information is used for controlling the extension of the electric cylinder;

the controller sends second control information to the electric cylinder.

Compared with the prior art, the utility model has the following beneficial effects:

1. before detection, the utility model extrudes and shields the measuring point contact through the shielding component, so that the contact is contracted in the detection part, and the outside object is difficult to impact and damage the contact, thereby being beneficial to protecting the measuring point contact in an unused state.

2. Through the surface laminating that makes shielding plate's surface and detection portion, insert the detection portion and wait to detect the inside in-process of hole, shielding plate can shelter from the protection to the measurement station contact all the time to the measurement station contact is in the in-process that gets into waiting to detect the hole, is in the shrink state, and can not take place the striking with the pore wall, and then through setting up shielding plate, can effectively protect the measurement station contact, operating personnel can insert fast at the testing process, and then is favorable to improving detection efficiency.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is an enlarged schematic view of the structure of fig. 1 according to the present utility model.

Fig. 3 is a schematic diagram of the structure of the hand-hold part, the controller and the detecting part of the utility model.

Fig. 4 is an enlarged schematic view of the structure of fig. 3 at B according to the present utility model.

Fig. 5 is a schematic view of the structure of the supporting block and the shielding plate of the present utility model.

Fig. 6 is an enlarged schematic view of the structure of fig. 5 at C according to the present utility model.

Fig. 7 is a schematic sectional view of a fixed part and a sliding part according to the present utility model.

Fig. 8 is a schematic structural view of a support block according to the present utility model.

Fig. 9 is a schematic sectional view of a mounting cylinder according to the present utility model.

FIG. 10 is a flow chart of the detection method of the present utility model.

In the figure: 1. a hand-held part; 2. a controller; 3. a detection unit; 4. a measuring point contact; 5. a shielding plate; 501. a fixing part; 502. a sliding part; 6. a support block; 7. a mounting ring; 8. a mounting groove; 9. a guide rod; 10. a slide block; 11. a gas spring; 12. a straight groove; 13. a chute; 14. a vertical groove; 15. a first spring; 16. a ball; 17. an electric cylinder; 18. a pushing plate; 19. a double-layer splint; 20. a bolt; 21. a mounting cylinder; 22. a sliding cylinder; 23. an extrusion plate; 24. a second spring; 25. a pressure sensor; 26. a workpiece.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art.

An automatic aperture detection adjusting device for automobile mold production as shown in fig. 1 to 9, comprising:

the portable electronic device comprises a handheld part 1, wherein a controller 2 is arranged at the top end of the handheld part 1;

the detection part 3 is rotatably connected to the bottom end of the handheld part 1;

the contact assembly is arranged on the surface of the detection part 3 and is used for detecting the aperture;

the shielding assembly comprises a shielding plate 5, the shielding plate 5 is used for extruding and shielding the measuring point contact 4 of the contact assembly, and when the detecting part 3 is inserted into the hole to be detected, the shielding plate 5 moves vertically upwards to enable the measuring point contact 4 to stably enter the hole to be detected;

in the prior art, when the gauge is used for detection, the gauge is inserted into a hole to be detected of a workpiece 26, the gauge contacts 4 are contacted with the hole wall, and then the gauge is rotated to enable the gauge contacts 4 to rotate in the hole for measurement;

it should be noted that, under the normal state, the measuring point contact 4 is in a protruding state under the pushing of the internal spring, and can directly collide with the outer wall of the hole during detection, so that the contact is extremely damaged, and in the daily operation process, an operator needs to carefully insert the measuring tool slowly into the hole to be detected by the wing, so that the strong collision damage to the measuring point contact 4 is avoided, and the operator is difficult to detect quickly;

it should be further noted that, in the detection principle of the measuring tool in the prior art, the aperture of the hole to be detected is obtained by measuring the horizontal displacement of the measuring point contact 4, which is the prior art, and will not be repeated here;

the working mode of the utility model is that before detection, the shielding component can squeeze and shield the measuring point contact 4, so that the contact is contracted in the detection part 3, and the outside object is difficult to impact and damage the contact, thereby being beneficial to protecting the measuring point contact 4 in an unused state;

because the surface of shielding plate 5 is laminated with the surface of detection portion 3, insert the in-process of waiting to detect downthehole portion with detection portion 3, shielding plate 5 can shelter from the protection to measurement station contact 4 all the time to measurement station contact 4 is in the in-process of waiting to detect the hole in the entering, is in the shrink state, and can not take place the striking with the pore wall, and then through setting up shielding plate 5, can effectively protect measurement station contact 4, operating personnel can insert fast at the detection in-process, and then is favorable to improving detection efficiency.

As a further embodiment of the utility model, the shielding assembly comprises:

a plurality of supporting blocks 6, wherein the top parts of the supporting blocks 6 are jointly fixed with a mounting ring 7, and the mounting ring 7 is fixed on the bottom surface of the hand-held part 1;

the mounting groove 8 is formed in the supporting block 6 close to the measuring point contact 4, and the shielding plate 5 is arranged in the mounting groove 8;

the guide grooves are formed in the outer walls of the two sides of the mounting groove 8, guide rods 9 are inserted into the guide grooves, and the guide rods 9 are fixed on the shielding plates 5;

the elastic pushing component is arranged between the shielding plate 5 and the inner top surface of the mounting groove 8 and is used for pushing the shielding plate 5 downwards;

as an alternative embodiment, as shown in fig. 8, the guide groove is a straight groove 12, and the guide rod 9 is inserted inside the straight groove 12;

specifically, under the blocking action of the outer wall of the workpiece 26, the shielding plate 5 moves upwards relative to the supporting block 6, under the guiding action of the guide rod 9 and the vertical groove 14, the shielding plate 5 can vertically move upwards and is far away from the contact, and the embodiment can be applied to the measuring point contact 4 with the spherical end, and when the supporting plate is vertically pressed down, the measuring point contact 4 can be directly extruded into the detection part 3 under the guiding of the spherical surface;

as another alternative embodiment, as shown in fig. 5, the guide groove includes a chute 13 and a vertical groove 14, the bottom end of the chute 13 communicates with the top end of the vertical groove 14, and the guide rod 9 is inserted inside the vertical groove 14; the shielding plate 5 comprises a fixed part 501 and a sliding part 502, wherein the sliding part 502 vertically slides on one side of the fixed part 501, the sliding part 502 is contacted with the measuring point contact 4, and a first spring 15 is arranged above the sliding part 502.

Specifically, when the guide groove is a combined groove formed by the chute 13 and the vertical groove 14, the guide rod 9 moves upwards along the vertical groove 14 in the process of lifting the shielding plate 5 relative to the supporting block 6, so that the measuring point contact 4 can stably enter the hole to be detected, and then the guide rod 9 enters the chute 13 along the top end of the vertical groove 14 and can gradually be far away from the detection part 3 under the guidance of the chute 13;

after the detection is completed, after the measuring point contact 4 moves out of the hole to be detected, the measuring point contact 4 is in a protruding state, in this embodiment, the sliding part 502 is arranged on the shielding plate 5, the vertical length of the shielding plate 5 is prolonged, when the elastic pushing component pushes the shielding plate to reset, the sliding part 502 can firstly extend to one side of the measuring point contact 4, but does not contact the measuring point contact 4, when the shielding plate 5 moves along the chute 13 to one side close to the measuring point contact 4, the sliding part 502 can approach and squeeze the measuring point contact 4 from the horizontal direction, and the measuring point contact 4 enters the detecting part 3 in a horizontal squeezing mode, so that the device can be suitable for the measuring point contacts 4 with various shapes on the market, such as cylinders, squares and the like.

As a further embodiment of the present utility model, the elastic pushing assembly comprises a slider 10, the slider 10 is slidably connected with the inner top surface of the mounting groove 8, and a gas spring 11 is commonly fixed between the bottom of the slider 10 and the top of the shielding plate 5;

specifically, in the detection process, under the blocking action of the workpiece 26, the shielding plate 5 moves upwards relative to the supporting block 6, the gas spring 11 is extruded, and when the shielding plate 5 is reset, the gas spring 11 can be pushed by the elastic force;

by providing the slider 10, the slider 10 can slide to give way when the shutter 5 moves along the chute 13.

As a further embodiment of the present utility model, the bottom of the support block 6 is provided with balls 16 through a connecting mechanism;

specifically, when the rotation measurement is performed, by providing the balls 16, the friction force between the support block 6 and the surface of the workpiece 26 can be reduced, thereby facilitating the rotation of the device.

As a further embodiment of the utility model, an electric cylinder 17 is fixed on the side wall of the supporting block 6, and a pushing plate 18 is fixed at the movable end of the electric cylinder 17;

specifically, after the balls 16 contact the surface of the workpiece 26, if the shielding plate 5 still contacts the workpiece 26, the rotation detection of the detecting portion 3 may be affected, by activating the electric cylinder 17, the electric cylinder 17 pushes the pushing plate 18, and the pushing plate 18 pushes the guiding rod 9 to continue to ascend along the chute 13, so that the shielding plate 5 ascends until the sliding portion 502 is separated from the workpiece 26, thereby reducing the influence of the shielding plate 5 on the rotation detection of the detecting portion 3.

As a further embodiment of the utility model, the connecting mechanism comprises a double-layer clamping plate 19, the balls 16 are embedded and installed on the double-layer clamping plate 19, bolts 20 are fixed at four corners of the double-layer clamping plate 19, a plurality of installation cylinders 21 are fixed in the bottom surface of the supporting block 6, a sliding cylinder 22 and a squeezing plate 23 are vertically and slidably connected in the installation cylinders 21, a second spring 24 is fixed between the squeezing plate 23 and the sliding cylinder 22, and the end parts of the bolts 20 are in threaded connection with the inner wall of the sliding cylinder 22;

the pressure sensor 25 is fixed to the inner top surface of one of the mounting cylinders 21;

specifically, during detection, as the detection part 3 is inserted into the hole to be detected, the ball 16 gradually contacts with the surface of the workpiece 26, the hand-held part 1 is manually pressed downwards, and the double-layer clamping plate 19 and the bolt 20 are fixed, so that the ball 16, the double-layer clamping plate 19 and the bolt 20 integrally move upwards, and the bolt 20 is fixed with the sliding cylinder 22, so that the bolt 20 drives the sliding cylinder 22 to upwards press the second spring 24;

the second spring 24 presses the pressure sensor 25 through the pressing plate 23, detects the pressure value through the pressure sensor 25, activates the extension of the electric cylinder 17 when the pressure value rises to a first preset value, activates the contraction of the electric cylinder 17 when the pressure value decreases to a second preset value,

the first preset value is larger than the second preset value, and the first preset value and the second preset value are set in the computer terminal in advance through operators.

The method for detecting the aperture for producing the automobile mould shown in fig. 10 comprises the following steps:

the controller 2 acquires first request information, and the first request information is generated after the pressure sensor 25 detects that the pressure value rises to a first preset value;

the controller 2 generates first control information according to the first request information, the first control information being used for controlling the extension of the electric cylinder 17;

the controller 2 sends first control information to the electric cylinder 17.

As a further embodiment of the present utility model, the detection method further comprises the steps of:

the controller 2 acquires second request information, and the second request information is generated after the pressure sensor 25 detects that the pressure value is reduced to a second preset value;

the controller 2 generates second control information according to the second request information, wherein the second control information is used for controlling the extension of the electric cylinder 17;

the controller 2 sends the second control information to the electric cylinder 17.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, but rather, the foregoing embodiments and description illustrate the principles of the utility model, and that various changes and modifications may be effected therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents.

Claims (10)

1. An automatic aperture detection adjusting device for automobile mold production, which is characterized by comprising:

a hand-held part (1), wherein a controller (2) is arranged at the top end of the hand-held part (1);

the detection part (3) is rotationally connected to the bottom end of the handheld part (1);

the contact assembly is mounted on the surface of the detection part (3) and is used for detecting the aperture;

the shielding assembly comprises a shielding plate (5), the shielding plate (5) is used for extruding and shielding a measuring point contact (4) of the contact assembly, and when the detecting part (3) is inserted into a hole to be detected, the shielding plate (5) moves vertically upwards to enable the measuring point contact (4) to stably enter the hole to be detected.

2. The automatic aperture detection and adjustment device for automobile mold production according to claim 1, wherein: the shielding assembly includes:

a plurality of supporting blocks (6), wherein the top parts of the supporting blocks (6) are jointly fixed with a mounting ring (7), and the mounting ring (7) is fixed on the bottom surface of the hand-held part (1);

the mounting groove (8) is formed in the supporting block (6) close to the measuring point contact (4), and the shielding plate (5) is arranged in the mounting groove (8);

the guide grooves are formed in the outer walls of the two sides of the mounting groove (8), guide rods (9) are inserted into the guide grooves, and the guide rods (9) are fixed on the shielding plates (5);

the elastic pushing assembly is arranged between the shielding plate (5) and the inner top surface of the mounting groove (8), and is used for pushing the shielding plate (5) downwards.

3. The automatic aperture detection adjusting device for automobile mold production according to claim 2, wherein: the guide groove is a straight groove (12), and the guide rod (9) is inserted into the straight groove (12).

4. The automatic aperture detection adjusting device for automobile mold production according to claim 2, wherein: the guide groove comprises a chute (13) and a vertical groove (14), the bottom end of the chute (13) is communicated with the top end of the vertical groove (14), and the guide rod (9) is inserted into the vertical groove (14);

the shielding plate (5) comprises a fixing part (501) and a sliding part (502), wherein the sliding part (502) vertically slides on one side of the fixing part (501), the sliding part (502) is in contact with the measuring point contact (4), and a first spring (15) is arranged above the sliding part (502).

5. The automatic aperture detection and adjustment device for automobile mold production according to claim 4, wherein: the elastic pushing assembly comprises a sliding block (10), the sliding block (10) is in sliding connection with the inner top surface of the mounting groove (8), and a gas spring (11) is fixed between the bottom of the sliding block (10) and the top of the shielding plate (5).

6. The automatic aperture detection and adjustment device for automobile mold production according to claim 4, wherein: the bottom of the supporting block (6) is provided with balls (16) through a connecting mechanism.

7. The automatic aperture detection and adjustment device for automobile mold production according to claim 6, wherein: an electric cylinder (17) is fixed on the side wall of the supporting block (6), and a pushing plate (18) is fixed at the movable end of the electric cylinder (17).

8. The automatic aperture detection and adjustment device for automobile mold production according to claim 7, wherein: the connecting mechanism comprises a double-layer clamping plate (19), balls (16) are embedded and arranged on the double-layer clamping plate (19), bolts (20) are respectively fixed at four corners of the double-layer clamping plate (19), a plurality of mounting cylinders (21) are fixed in the bottom surface of the supporting block (6), a sliding cylinder (22) and a squeezing plate (23) are vertically and slidably connected in the mounting cylinders (21), a second spring (24) is fixed between the squeezing plate (23) and the sliding cylinder (22), and the end portions of the bolts (20) are in threaded connection with the inner wall of the sliding cylinder (22).

9. The automatic aperture detection adjusting device for automobile mold production according to claim 8, wherein the automatic aperture detection adjusting device comprises: a pressure sensor (25) is fixed on the inner top surface of one of the mounting cylinders (21);

the detection method comprises the following steps:

the controller (2) acquires first request information, and the first request information is generated after the pressure sensor (25) detects that the pressure value rises to a first preset value;

the controller (2) generates first control information according to the first request information, wherein the first control information is used for controlling the extension of the electric cylinder (17);

the controller (2) sends first control information to the electric cylinder (17).

10. The method for detecting the aperture for the production of the automobile die according to claim 9, wherein: the detection method further comprises the following steps:

the controller (2) acquires second request information, and the second request information is generated after the pressure sensor (25) detects that the pressure value is reduced to a second preset value;

the controller (2) generates second control information according to the second request information, wherein the second control information is used for controlling the extension of the electric cylinder (17);

the controller (2) sends second control information to the electric cylinder (17).