CN211402201U

CN211402201U - Electronic component X-ray nondestructive testing device

Info

Publication number: CN211402201U
Application number: CN202020052888.4U
Authority: CN
Inventors: 谢光红; 赵红艳
Original assignee: Shenzhen Kangmu Intelligent Equipment Co Ltd
Current assignee: Shenzhen Kangmu Intelligent Equipment Co Ltd
Priority date: 2020-01-10
Filing date: 2020-01-10
Publication date: 2020-09-01
Anticipated expiration: 2030-01-10

Abstract

The utility model discloses an electronic component X-ray nondestructive test device, including first elevating system, second elevating system, translation mechanism, X-ray emitter, X-ray receiver, objective table. The first lifting mechanism is positioned above the translation mechanism; the second lifting mechanism is positioned below the translation mechanism. The X-ray receiver is arranged on the first lifting mechanism. The X-ray emitter is arranged on the second lifting mechanism. The objective table is arranged on the translation mechanism. The first lifting mechanism comprises a first lifting slide rail, a first lifting driving motor, a swinging driving motor and a cross beam. The swing driving motor is connected with the rotating shaft through a second transmission assembly. Swing driving motor drives first lift slide rail and inclines left and right on the crossbeam to the angle of adjustment X light receiver for the objective table realizes detecting the multi-angle of the electronic component that awaits measuring, easy operation, save check-out time, improved electronic component's detection efficiency.

Description

Electronic component X-ray nondestructive testing device

Technical Field

The utility model relates to a nondestructive inspection detects technical field, especially relates to an electronic component X-ray nondestructive test device.

Background

The electronic component X-Ray nondestructive testing device utilizes the change of light intensity of X-Ray (X-Ray) after penetrating through substances with different densities to generate a contrast effect which can form an image, and then the internal structure of the electronic component to be tested can be displayed, and further the defective area in the electronic component to be tested can be observed under the condition of not damaging the electronic component to be tested.

However, the conventional X-ray nondestructive testing device for electronic components has the following disadvantages: the angle and the position of the electronic element to be detected need to be manually adjusted, so that the requirement of all-dimensional detection of the electronic element is difficult to meet, the detection time is consumed, and the detection efficiency of the electronic element is low.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides an electronic component X-ray nondestructive test device.

In order to achieve the above purpose, the utility model discloses technical scheme as follows:

an X-ray nondestructive testing device for electronic components comprises a first lifting mechanism, a second lifting mechanism, a translation mechanism, an X-ray emitter, an X-ray receiver and an object stage. The first lifting mechanism is positioned above the translation mechanism; the second lifting mechanism is positioned below the translation mechanism. The X-ray receiver is arranged on the first lifting mechanism. The X-ray emitter is arranged on the second lifting mechanism. The objective table is arranged on the translation mechanism.

The first lifting mechanism comprises a first lifting slide rail, a first lifting driving motor, a swinging driving motor and a cross beam. The first lifting slide rail is installed on the cross beam through a rotating shaft. The first lifting driving motor and the swinging driving motor are arranged on the first lifting slide rail. The X-ray receiver can be arranged on the first lifting slide rail in a sliding way. The first lifting driving motor is connected with the X-ray receiver through the first transmission assembly. The swing driving motor is connected with the rotating shaft through a second transmission assembly.

Optionally, the second lifting mechanism includes a second lifting slide rail and a second lifting driving motor. The second lifting slide rail is arranged below the objective table. The second lifting driving motor is arranged on the second lifting slide rail. The X-ray emitter can be arranged on the second lifting slide rail in a sliding way. And a rotating shaft of the second lifting driving motor is connected with the X-ray emitter through a third transmission component.

Optionally, a disk is arranged in the middle of the object stage, and a rotary driving motor is arranged on the object stage. The rotary driving motor is connected to the disc through a rotating shaft of the fourth transmission assembly. The rotary driving motor is used for driving the disc to rotate.

Optionally, the translation mechanism includes an X-axis carriage, a Y-axis carriage, an X-axis drive motor, and a Y-axis drive motor. The Y-axis sliding frame is arranged on the X-axis sliding frame in a sliding way. The object stage is slidably mounted on the Y-axis sliding frame. The X-axis driving motor is arranged on the X-axis sliding frame. The Y-axis driving motor is arranged on the Y-axis sliding frame. And a rotating shaft of the X-axis driving motor is connected to the Y-axis sliding frame through a fifth transmission assembly. And a rotating shaft of the Y-axis driving motor is connected to the objective table through a sixth transmission assembly.

Optionally, the second transmission assembly is a gear set, a guide rod or a chain.

Optionally, a rotating shaft of the swing driving motor and a rotating shaft are respectively provided with a gear. And a rotating shaft of the swing driving motor is connected with a gear on the rotating shaft through a second transmission component.

Optionally, the first lifting slide rail is slidably provided with a mounting seat. The X-ray receiver is arranged on the mounting seat. The rotating shaft of the first lifting driving motor is connected with the mounting seat through a first transmission assembly.

Optionally, the heat dissipation device further comprises a chassis and a heat dissipation plate. The first lifting mechanism, the second lifting mechanism, the translation mechanism, the X-ray emitter, the X-ray receiver and the object stage are arranged in the machine shell. A safety door is arranged in front of the casing; the safety door faces the objective table. The back of the machine shell is provided with a heat dissipation plate mounting position. The heat dissipation plate is arranged on the heat dissipation plate mounting position; the heat dissipation plate is provided with a plurality of heat dissipation holes.

Optionally, the heat dissipation holes on the heat dissipation plate are distributed in a matrix.

The utility model has the advantages that:

(1) swing driving motor drives first lift slide rail and inclines left and right on the crossbeam to adjustment X light receiver need not the artifical electronic component that awaits measuring that swings on the objective table for the angle of objective table, realizes the multi-angle detection to the electronic component that awaits measuring, easy operation, save check-out time, has improved electronic component's detection efficiency.

(2) The rotary driving motor drives the disc on the objective table to rotate, so that the all-dimensional detection of the electronic element to be detected is realized, and the detection requirement of the electronic element to be detected is met.

(3) Translation mechanism, first elevating system, second elevating system can automatic adjustment X-ray emitter, X-ray receiver and objective table between distance and the angle, realize the automated inspection to the electronic component that awaits measuring, reduce the cost of labor, improved electronic component's detection efficiency.

Drawings

Fig. 1 is a schematic view of the three-dimensional structure of the first viewing angle of the X-ray nondestructive testing apparatus for middle electronic components according to the present invention.

Fig. 2 is a schematic view of the second view angle of the X-ray nondestructive testing apparatus for middle electronic components according to the present invention.

Wherein the reference numerals of fig. 1 to 2 are: the X-ray detector comprises a first lifting mechanism 1, a second lifting mechanism 2, a translation mechanism 3, an X-ray emitter 4, an X-ray receiver 5 and an object stage 6; a disc 61, a rotary drive motor 62; an X-axis sliding frame 31, a Y-axis sliding frame 32, an X-axis driving motor 33 and a Y-axis driving motor 34; the device comprises a first lifting slide rail 11, a first lifting driving motor 12, a swinging driving motor 13 and a cross beam 14; a second lifting slide rail 21 and a second lifting driving motor 22.

Detailed Description

The invention is further explained below with reference to the drawings and examples.

As shown in fig. 1 to 2, an X-ray nondestructive testing apparatus for electronic components includes a first lifting mechanism 1, a second lifting mechanism 2, a translation mechanism 3, an X-ray emitter 4, an X-ray receiver 5, and an object stage 6.

The first lifting mechanism 1 is positioned above the translation mechanism 3; the second lifting mechanism 2 is located below the translation mechanism 3. The X-ray receiver 5 is mounted on the first elevating mechanism 1. The X-ray emitter 4 is mounted on the second elevating mechanism 2. The stage 6 is mounted on the translation mechanism 3.

The first lifting mechanism 1 is used for driving the X-ray receiver 5 to ascend or descend. The second lifting mechanism 2 is used for driving the X-ray emitter 4 to ascend or descend. The translation mechanism 3 is used for driving the object stage 6 to move transversely or longitudinally on a plane. The object stage 6 is used for bearing the electronic element to be tested.

In some embodiments, the first lifting mechanism 1 includes a first lifting slide rail 11, a first lifting driving motor 12, a swinging driving motor 13, and a cross beam 14.

The first lifting slide 11 is mounted on a cross beam 14 by means of a rotating shaft. The first lifting driving motor 12 and the swinging driving motor 13 are installed on the first lifting slide rail 11. The X-ray receiver 5 is slidably mounted on the first elevation slide rail 11. The rotating shaft of the first lifting driving motor 12 is connected with the X-ray receiver 5 through a first transmission assembly. The rotating shaft of the swing driving motor 13 is connected with the rotating shaft through a second transmission assembly. The first transmission component and the second transmission component are respectively arranged in the cavity of the first lifting slide rail 11.

Specifically, a rotation shaft of the swing drive motor 13 and the rotation shaft are provided with gears, respectively. The second transmission component can be a gear set, a guide rod or a chain and the like. The rotating shaft of the swing driving motor 13 is connected with the gear on the rotating shaft through a second transmission assembly. The rotating shaft of the swing driving motor 13 can rotate forward or backward, and under the transmission of the second transmission assembly, the rotating shaft rotates forward or backward, so that the first lifting slide rail 11 is driven to incline leftwards or rightwards. Because the X-ray receiver 5 is mounted on the first lifting slide rail 11, the angle of the X-ray receiver 5 relative to the electronic component to be tested on the object stage 6 can be adjusted after the first lifting slide rail 11 is inclined, so that the X-ray receiver 5 can acquire X-ray images of the electronic component to be tested at different angles. Alternatively, the rotation shaft of the swing driving motor 13 makes ± 45 ° rotation.

Similarly, the first transmission component can be a gear set, a guide rod or a chain. Optionally, a first mounting seat is slidably mounted on the first lifting slide rail 11. The X-ray receiver 5 is mounted on the first mount. The rotating shaft and the mounting seat of the first lifting driving motor 12 are respectively provided with a gear. The rotating shaft of the first lifting driving motor 12 is connected with the gear on the first mounting seat through a first transmission assembly. The rotating shaft of the first lifting driving motor 12 rotates forward or reversely, and drives the first mounting base to ascend or descend through the first transmission assembly, so that the distance between the X-ray receiver 5 and the electronic element to be measured is adjusted.

In some embodiments, the second lifting mechanism 2 includes a second lifting slide 21 and a second lifting driving motor 22.

The second lifting slide rail 21 is provided below the stage 6. The second elevation driving motor 22 is installed on the second elevation slide rail 21. The X-ray emitter 4 is slidably mounted on the second elevation slide rail 21. The rotating shaft of the second lifting driving motor 22 is connected with the X-ray emitter 4 through a third transmission component. The third transmission assembly is installed in the cavity of the second lifting slide rail 21.

The third transmission component can be a gear set, a guide rod or a chain and the like. Optionally, a second mounting seat is slidably mounted on the second lifting/lowering sliding rail 21. The X-ray emitter 4 is mounted on the second mount. The rotating shaft of the second lifting driving motor 22 and the second mounting seat are respectively provided with a gear. The gear on the rotating shaft of the second lifting driving motor 22 is connected with the gear on the second mounting base through a third transmission assembly. The rotating shaft of the second lifting driving motor 22 rotates forward or backward, and drives the second mounting base to ascend or descend through the third transmission assembly, so as to adjust the distance between the X-ray emitter 4 and the electronic component to be measured.

In some embodiments, a base is disposed in the middle of the stage 6, a disk 61 is mounted on the base, and a rotation driving motor 62 is mounted on the stage 6. The rotation shaft of the rotation driving motor 62 is connected to the disc 61 through a fourth transmission assembly. The rotary drive motor 62 is used to rotate the disc 61 around the base. Optionally, the fourth drive assembly is a track that is wrapped around the disc 61.

In some embodiments, the translation mechanism 3 includes an X-axis carriage 31, a Y-axis carriage 32, an X-axis drive motor 33, and a Y-axis drive motor 34.

The Y-axis carriage 32 is slidably mounted on the X-axis carriage 31. The stage 6 is slidably mounted on the Y-axis carriage 32. An X-axis drive motor 33 is mounted on the X-axis carriage 31. A Y-axis drive motor 34 is mounted on the Y-axis carriage 32. The rotating shaft of the X-axis driving motor 33 is connected to the Y-axis carriage 32 through a fifth transmission assembly. The rotating shaft of the Y-axis drive motor 34 is connected to the stage 6 through a sixth transmission assembly.

Specifically, the fifth transmission assembly and the sixth transmission assembly are guide rods. The side parts of the X-axis sliding frame 31 and the Y-axis sliding frame 32 are respectively provided with a threaded through hole. The threaded through hole is matched with the guide rod. The rotation shaft of the X-axis driving motor 33 rotates forward or backward, and the Y-axis carriage 32 is driven by the guide rod to move forward or backward along the direction of the slide rail of the X-axis carriage 31. Similarly, the rotation shaft of the Y-axis driving motor 34 rotates forward or backward, and the stage 6 is driven by the guide rod to move forward or backward along the slide rail of the Y-axis carriage 32.

In some embodiments, the X-ray nondestructive testing device for workpieces further comprises a machine shell and a heat dissipation plate.

The first lifting mechanism 1, the second lifting mechanism 2, the translation mechanism 3, the X-ray emitter 4, the X-ray receiver 5 and the object stage 6 are arranged in the machine shell. A safety door is arranged in front of the casing; the security gate faces the stage 6. The back of the machine shell is provided with a heat dissipation plate mounting position. The heat dissipation plate is arranged on the heat dissipation plate mounting position; the heat dissipation plate is provided with a plurality of heat dissipation holes. The case and the heat dissipation plate are made of lead material. Optionally, the heat dissipation holes on the heat dissipation plate are distributed in a matrix.

The electronic component that awaits measuring is placed on objective table 6 from the emergency exit, and in the testing process, close the emergency exit, the heat that sends each part in with the casing through the heating panel in time gives off the external world and goes, avoids causing the part to damage because of the heat dissipation untimely.

In some embodiments, the bottom of the housing is equipped with a plurality of universal wheels to facilitate movement of the device.

Above-mentioned embodiment, swing driving motor 13 drives first lift slide rail 11 and inclines left or right on crossbeam 14 to adjustment X light receiver 5 need not the manual work and swings the electronic component that awaits measuring on the objective table 6 for the angle of objective table 6, realizes the multi-angle detection to the electronic component that awaits measuring, easy operation, save check-out time, has improved electronic component's detection efficiency. The rotary driving motor 62 drives the disc 61 on the objective table 6 to rotate, so that the all-dimensional detection of the electronic element to be detected is realized, and the detection requirement of the electronic element to be detected is met. Translation mechanism 3, first elevating system 1, second elevating system 2 can automatic adjustment X light emitter 4, X light receiver 5 and objective table 6 between distance and the angle, realize the automated inspection to the electronic component that awaits measuring, reduce the cost of labor, improved electronic component's detection efficiency.

What has been described above is only an optional embodiment of the present invention, and the present invention is not limited to the above embodiments. It is understood that other modifications and variations directly derivable or suggested by a person skilled in the art without departing from the basic idea of the invention are considered to be within the scope of protection of the invention.

Claims

1. An electronic component X-ray nondestructive testing device is characterized in that:

comprises a first lifting mechanism (1), a second lifting mechanism (2), a translation mechanism (3), an X-ray emitter (4), an X-ray receiver (5) and an object stage (6);

the first lifting mechanism (1) is positioned above the translation mechanism (3); the second lifting mechanism (2) is positioned below the translation mechanism (3); the X-ray receiver (5) is arranged on the first lifting mechanism (1); the X-ray emitter (4) is arranged on the second lifting mechanism (2); the objective table (6) is arranged on the translation mechanism (3);

the first lifting mechanism (1) comprises a first lifting slide rail (11), a first lifting driving motor (12), a swinging driving motor (13) and a cross beam (14); the first lifting slide rail (11) is arranged on the cross beam (14) through a rotating shaft; a first lifting driving motor (12) and a swinging driving motor (13) are arranged on the first lifting slide rail (11); the X-ray receiver (5) can be arranged on the first lifting slide rail (11) in a sliding way; the first lifting driving motor (12) is connected with the X-ray receiver (5) through a first transmission assembly; and the swing driving motor (13) is connected with the rotating shaft through a second transmission assembly.

2. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

the second lifting mechanism (2) comprises a second lifting slide rail (21) and a second lifting driving motor (22);

the second lifting slide rail (21) is arranged below the objective table (6);

the second lifting driving motor (22) is arranged on the second lifting slide rail (21);

the X-ray emitter (4) can be arranged on the second lifting slide rail (21) in a sliding way;

the rotating shaft of the second lifting driving motor (22) is connected with the X-ray emitter (4) through a third transmission component.

3. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

a disc (61) is arranged in the middle of the objective table (6), and a rotary driving motor (62) is arranged on the objective table (6);

the rotating shaft of the rotating drive motor (62) is connected to the disc (61) through a fourth transmission assembly;

the rotary driving motor (62) is used for driving the disc (61) to rotate.

4. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

the translation mechanism (3) comprises an X-axis sliding frame (31), a Y-axis sliding frame (32), an X-axis driving motor (33) and a Y-axis driving motor (34);

the Y-axis sliding frame (32) is arranged on the X-axis sliding frame (31) in a sliding way;

the objective table (6) is arranged on the Y-axis sliding frame (32) in a sliding way;

an X-axis driving motor (33) is arranged on the X-axis sliding frame (31);

a Y-axis driving motor (34) is arranged on the Y-axis sliding frame (32);

a rotating shaft of the X-axis driving motor (33) is connected to the Y-axis sliding frame (32) through a fifth transmission assembly;

the rotating shaft of the Y-axis driving motor (34) is connected to the objective table (6) through a sixth transmission assembly.

5. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

the second transmission assembly is a gear set, a guide rod or a chain.

6. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

gears are respectively arranged on a rotating shaft of the swing driving motor (13) and the rotating shaft;

and a gear on a rotating shaft of the swing driving motor (13) is connected with a gear on the rotating shaft through the second transmission assembly.

7. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

the first lifting slide rail (11) is slidably provided with a mounting seat;

the X-ray receiver (5) is arranged on the mounting seat;

and a rotating shaft of the first lifting driving motor (12) is connected with the mounting seat through the first transmission assembly.

8. The X-ray nondestructive inspection apparatus for electronic components according to claim 1, characterized in that:

the heat dissipation device also comprises a machine shell and a heat dissipation plate;

the first lifting mechanism (1), the second lifting mechanism (2), the translation mechanism (3), the X-ray emitter (4), the X-ray receiver (5) and the objective table (6) are arranged in the machine shell;

a safety door is arranged in front of the shell; the safety door faces the objective table (6);

the back of the shell is provided with a heat dissipation plate mounting position;

the heat dissipation plate is arranged on the heat dissipation plate mounting position; the heat dissipation plate is provided with a plurality of heat dissipation holes.

9. The X-ray nondestructive inspection apparatus for electronic components according to claim 8, characterized in that:

the radiating holes in the radiating plate are distributed in a matrix.