CN117330591A - Heating in-situ device of X-ray inspection machine - Google Patents

Abstract

The invention discloses a heating in-situ device of an X-ray inspection machine, which comprises a box body, wherein a bearing clamping assembly is arranged in the box body and is at least used for bearing a product and clamping and fixing the product; the cover body is hinged with one side of the box body and is at least used for sealing the box body; the heating piece is arranged on the cover body and is at least used for heating the inner space of the box body; the heat dissipation piece is arranged close to the box body and is at least used for dissipating heat and cooling the inner space of the box body. When the X-ray CT detector is used for detecting the product, the product state at different temperatures can be reconstructed, the characteristics of the product can be more accurately understood and known, and more basis is provided for the use of the product in a production line and the problem analysis.

Description

Heating in-situ device of X-ray inspection machine

Technical Field

The invention relates to the technical field of X-ray detectors, in particular to a heating in-situ device of an X-ray detector.

Background

An X-ray detector, such as an X-ray CT detector, is a device that can analyze the internal structure of a test object without damage. The principle is that an X-ray irradiates an object to be detected, different structures in the object to be detected absorb different X-rays, black-and-white imaging patterns with different intensities are formed on a flat panel detector after the X-rays pass through the object to be detected, the X-ray source and the flat panel detector take photos at different angle positions relative to the object to be detected, and the object to be detected can form a 3D image, abbreviated as 3D reconstruction, on software through a certain algorithm. Through the development of some in-situ experimental devices, the process states of the product under the action of different environments can be studied in situ in real time by utilizing the X-ray detection equipment, so that the characteristics of the product can be more accurately understood and known, and more basis is provided for the use of the product in a production line and the analysis of problems.

In the SMT industry, for components on a circuit board, in reflow soldering after brushing tin and pasting, products in different states can be obtained by controlling different temperature states, and under the condition of controlling soldering defects, an X-ray detection device can be used for analyzing solder ball states between a pasting element and the circuit board. The tin soldering process of the chip device under different temperature environments and under different furnace temperature curves is researched, so that the occurrence of bad defects of products under different temperatures is predicted, and the method has important significance for improving the research and development of the soldering of the chip device in the SMT industry.

At present, in the SMT industry, the circuit board after the completion of soldering tin is detected through the X-ray detection equipment (AXI equipment), the abnormal situation occurring in the soldering tin process is analyzed and judged through the defect situation after the soldering tin, and then the parameters of the reflow soldering equipment are adjusted to meet the production, but the real-time state of the key points cannot be detected in the soldering tin process in the existing mode, so that the bad factors of the welding cannot be accurately analyzed and appear in which temperature link, and therefore, an in-situ experimental device needs to be developed to study the process state of the product under the action of different temperature environments.

Disclosure of Invention

The invention aims to provide a heating in-situ device of an X-ray inspection machine, which can reconstruct the product states at different temperatures when detecting products by an X-ray CT detector, can more accurately understand and know the characteristics of the products, and provides more basis for product use and problem analysis in a production line.

In order to achieve the above purpose, the following technical scheme is adopted:

a heating in-situ device of an X-ray inspection machine comprises

The box body is internally provided with a bearing and clamping assembly which is at least used for bearing products and clamping and fixing the products;

the cover body is hinged with one side of the box body and is at least used for sealing the box body;

the heating piece is arranged on the cover body and is at least used for heating the inner space of the box body;

the heat dissipation piece is arranged close to the box body and is at least used for dissipating heat and cooling the inner space of the box body.

Further, the bearing clamping assembly comprises a first guide rail and a second guide rail; the first guide rail and the second guide rail are arranged in the box body at intervals in parallel, the first guide rail is also connected with two first sliding blocks in a sliding manner, and the second guide rail is also connected with two second sliding blocks in a sliding manner; a limiting guide rail is also connected between each first sliding block and each second sliding block, and the two limiting guide rails are arranged in parallel at intervals; and two opposite sides of the two limit guide rails are respectively provided with a limit groove, and two ends of the product are respectively inserted into one limit groove for arrangement.

Further, the two limit guide rails are also connected with positioning clamping blocks in a sliding manner, and the positioning clamping blocks are at least used for clamping and fixing two sides of a product; and the positioning clamping block, the first sliding block and the second sliding block are also provided with locking knobs.

Further, the heating in-situ device of the X-ray inspection machine also comprises a base and a bearing frame; a first mounting groove is formed in the top of the base, and a carbon fiber bottom plate is further arranged in the first mounting groove; the carbon fiber bottom plate is provided with a first heat insulation plate, and the box body is arranged on the first heat insulation plate; the box body is provided with a first containing cavity with an opening at the top, and the inner wall of the first containing cavity is also provided with a second heat insulation plate; the bearing frame is arranged in the first accommodating cavity, and the outer wall of the bearing frame is clung to the second heat insulation plate; the bearing clamping assembly is arranged in the bearing frame.

Further, the cover body comprises a rotary gland and a rotary hinge; the rotary gland is hinged with the upper part of one side of the box body through a rotary hinge; a third heat insulation plate is arranged on one side, close to the box body, of the rotary gland, and a first panel is further arranged on the third heat insulation plate; the heating element is arranged on the first panel; and the other side of the rotary gland is also provided with a carbon fiber pressing plate.

Further, at least one first fixing block is arranged on one side of the first panel, and an arc-shaped clamping groove is formed in the first fixing block; the heating piece comprises a heating pipe which is clamped in the arc-shaped clamping groove; the first fixing block is further provided with a first compacting plate which is arranged on the heating pipe in a pressing mode and used for fixing the heating pipe in the arc-shaped clamping groove in a pressing mode.

Further, one side of the box body is also connected with an electric control box, one side of the box body is also provided with a wire passing hole which penetrates into the electric control box, and a temperature controller, a thermometer and a heating control module are also arranged in the electric control box; the heating control module is connected with the heating pipe, and the temperature controller is connected with the heating control module; the temperature instrument is connected with the temperature control module; and a thermocouple is also arranged in the box body and is connected with a thermometer.

Further, the heat sink comprises a heat dissipation fan; an air inlet communicated with the electric control box is formed in one side, close to the electric control box, of the box body, and a cooling fan is arranged in the electric control box and is arranged close to the air inlet; an air outlet is further formed in one end, away from the air inlet, of the other side of the box body.

Further, a first guide cover and a second guide cover are respectively arranged at the positions corresponding to the air inlet and the air outlet on the inner wall of the box body; the first guide cover is provided with an air inlet channel with an opening at one end and communicated with the air inlet, and the second guide cover is provided with an air outlet channel with an opening at one end and communicated with the air outlet.

Further, an annular clamping groove is formed in the top of the box body, and a sealing ring is embedded in the annular clamping groove.

By adopting the scheme, the invention has the beneficial effects that:

reasonable in design, convenient to use, when examining the product through X ray CT detects the machine, can reconstruct the product state under the different temperatures, can understand more accurately and learn the characteristic of product, provide more basis for the product is in production line use and problem analysis.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is an exploded view of the present invention;

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

FIG. 4 is a top view of FIG. 1;

wherein, the attached drawings mark and illustrate:

1, a box body; 2-a load-bearing clamping assembly; 3-a cover body; 4-a heating element; 5-a heat dissipation element; 6, a base; 7-a carrying frame; 8, an electric cabinet; 11-a wire via; 12-an air inlet; 13, an air outlet; 14-a first guide hood; 15-a second guide hood; 16-a sealing ring; 17-pulling buckle; 18-buckling lugs; 19-a handle; 20-a handle; 21-a first rail; 22-a second guide rail; 23-a first slider; 24-a second slider; 25-a limit guide rail; 26-positioning clamping blocks; 27-locking knob; 31-rotating the gland; 32-a third heat insulating plate; 33-a first panel; 34-a carbon fiber pressing plate; 35-a first fixed block; 36-arc clamping groove; 37-a first compacting plate; 61-a carbon fiber soleplate; 62—a first heat shield; 63—a second insulating panel; 81—a temperature controller; 82-thermometer; 83—a heating control module; 84-thermocouple; 85-mounting blocks; 86—a first position sensor; 87-a second position sensor.

Detailed Description

The invention will be described in detail below with reference to the drawings and the specific embodiments.

Referring to FIGS. 1 to 4, the present invention provides a heating in-situ apparatus for an X-ray inspection machine, in one embodiment, comprising

The box body 1 is internally provided with a bearing and clamping assembly 2, and the bearing and clamping assembly 2 is at least used for bearing products and clamping and fixing the products;

the cover body 3 is hinged with one side of the box body 1, and the cover body 3 is at least used for sealing the box body 1;

a heating element 4, wherein the heating element 4 is installed on the cover body 3, and the heating element 4 is at least used for heating the inner space of the box body 1;

the heat dissipation piece 5, the heat dissipation piece 5 is close to box 1 and arranges, is used for carrying out heat dissipation cooling to the inner space of box 1 at least.

With continued reference to fig. 1 to 4, in this embodiment, a pull buckle 17 is further installed on a side of the case 1 away from the cover 3, a buckle 18 matched with the pull buckle 17 is further installed on a corresponding portion of one side of the cover 3 and the pull buckle 17, after the cover 3 is covered, the cover 3 can be locked and fixed through the pull buckle 17 and the buckle 18, meanwhile, a handle 20 is further installed on a side of the cover 3 provided with the buckle 18, so that a worker can conveniently open or close the cover 3, and in addition, a handle 19 is further installed on each of two ends of the case 1, so that the worker can conveniently carry the case 1.

When the device is used, the cover body 3 can be opened firstly, then the product to be detected is placed on the bearing and clamping assembly 2, and the bearing and clamping assembly 2 can clamp and fix the product to be detected; then, cover the body 3, at this moment, the heating element 4 is located in the box 1, then carry the box 1 or flow into the X-ray detection machine through the track, then, heat the inner space of the box 1 through the heating element 4 and raise the temperature, then in the heating state, keep warm state, molten state, welding state, cooling state (can dispel the heat it through the heat sink 5) different temperature points under, obtain the product image (can adjust both and the position of product to be detected through adjusting X-ray source and flat panel detector of X-ray detection machine, in order to obtain the product image of different angles), through the image, just can see the product state to be detected under different temperature curves, in this embodiment, can be used to detect the soldering condition of circuit board, can obtain the tin ball between paster piece and the circuit board, 3D change image under different temperature states, finally, through CT section analysis problem, in order to provide more basis for the product in the use of production line and problem analysis.

In one embodiment, the carrying and clamping assembly 2 comprises a first guide rail 21 and a second guide rail 22; the first guide rail 21 and the second guide rail 22 are arranged in the box body 1 at intervals in parallel, the first guide rail 21 is also connected with two first sliding blocks 23 in a sliding manner, and the second guide rail 22 is also connected with two second sliding blocks 24 in a sliding manner; a limiting guide rail 25 is also connected between each first sliding block 23 and a second sliding block 24, and the two limiting guide rails 25 are arranged in parallel and at intervals; the opposite sides of the two limit guide rails 25 are also provided with a limit groove respectively, and two ends of the product are respectively inserted into the limit groove.

In this embodiment, when placing the product, the first slider 23 and the second slider 24 can be manually slid to adjust the distance between the two limit rails 25 so as to place products with different specifications and sizes, then, two ends of the product are respectively inserted into a limit groove, and then the first slider 23 and the second slider 24 are slid so as to make the two limit rails 25 close to each other, and further, the two ends of the product are clamped, so that the stability of placing the product is ensured, so that the X-ray detector can detect the product, and meanwhile, the product is not in direct contact with the inner wall of the box 1, so that the problem that the heating characteristics of the detected product are disturbed by other heat caused by heat conduction in the heating process can be avoided.

In addition, in this embodiment, the two limiting rails 25 are also slidably connected with positioning clamping blocks 26, and the positioning clamping blocks 26 are at least used for clamping and fixing two sides of a product; locking knobs 27 are also arranged on the positioning clamping blocks 26, the first sliding blocks 23 and the second sliding blocks 24. Through adjusting the position of two location clamp splice 26, can press from both sides tight fixedly with the both sides of product, can further improve the stability that the product was placed, after the product presss from both sides steadily, the accessible is screwed locking knob 27 to with location clamp splice 26, first slider 23 and second slider 24 locking fixedly, avoid when carrying box 1, because of location clamp splice 26, first slider 23 and second slider 24 relative slip, and lead to the product to place unstable problem.

In one embodiment, the heating in-situ device of the X-ray inspection machine further comprises a base 6 and a bearing frame 7; a first mounting groove is formed in the top of the base 6, and a carbon fiber bottom plate 61 is further arranged in the first mounting groove; the carbon fiber bottom plate 61 is provided with a first heat insulation plate 62, and the box body 1 is arranged on the first heat insulation plate 62; the box body 1 is provided with a first containing cavity with an opening at the top, and the inner wall of the first containing cavity is also provided with a second heat insulation plate 63; the bearing frame 7 is arranged in the first accommodating cavity, and the outer wall of the bearing frame 7 is clung to the second heat insulation plate 63; the load clamping assembly 2 is mounted within a load frame 7. In this embodiment, the first cavity is rectangular, that is, the inner walls of four sides of the first cavity are respectively provided with a second heat insulation board 63, after the cover body 3 is covered, the bottom and the periphery of the box body 1 can be insulated by the first heat insulation board 62 and the second heat insulation board 63, so that the heat loss is avoided from being too fast, and the detection precision is affected.

Further, in this embodiment, the cover 3 includes a rotary gland 31, a rotary hinge; the rotary gland 31 is hinged with the upper part of one side of the box body 1 through a rotary hinge; a third heat insulation plate 32 is arranged on one side, close to the box body 1, of the rotary gland 31, and a first panel 33 is further arranged on the third heat insulation plate 32; the heating element 4 is mounted on the first panel 33; the other side of the rotary gland 31 is also provided with a carbon fiber pressing plate 34. After the cover body 3 is covered, a sealed space can be formed inside the box body 1, the third heat insulation plate 32 on the rotary pressing cover 31 can insulate heat on the top of the box body 1, and then the first heat insulation plate 62 and the second heat insulation plate 63 are matched, so that the box body 1 can be in a completely heat insulation space, heat outflow can be avoided, and the detection precision is affected.

In an embodiment, at least one first fixing block 35 is mounted on one side of the first panel 33, and an arc-shaped slot 36 is further formed on the first fixing block 35; the heating piece 4 comprises a heating pipe which is clamped in the arc-shaped clamping groove 36; the first fixing block 35 is further provided with a first pressing plate 37, and the first pressing plate 37 is pressed on the heating pipe and is used for pressing and fixing the heating pipe in the arc-shaped clamping groove 36.

In this embodiment, the number of first fixed blocks 35 is equipped with three, and three first fixed blocks 35 are triangle-shaped arrangement (each first fixed block 35 is arranged on a summit of triangle-shaped), and the heating tube card is located in arc draw-in groove 36, through setting up three first fixed blocks 35, can increase the heating tube card and locate the area in the arc draw-in groove 36, improves the steadiness of its placing, simultaneously, still is equipped with first pinch plate 37, can compress tightly the heating pipe fixedly, avoids at the transport box 1 in-process, because of box 1 rocks and leads to the heating pipe to rock, drop or collide and then the risk of damage with box 1 inner wall.

In an embodiment, one side of the box body 1 is further connected with an electric control box 8, one side of the box body 1 is further provided with a wire passing hole 11 penetrating into the electric control box 8, and a temperature controller 81, a temperature meter 82 and a heating control module 83 are further installed in the electric control box 8; the heating control module 83 is connected with the heating pipe, and the temperature controller 81 is connected with the heating control module 83; the temperature meter 82 is connected with a temperature control module; a thermocouple 84 is also installed in the box body 1, and the thermocouple 84 is connected with the thermometer 82.

In this embodiment, the mounting block 85 is further mounted on the limit rail 25, the thermocouple 84 is mounted on the mounting block 85, meanwhile, the box 1 is further provided with the wire passing hole 11, the wire passing hole 11 can be conveniently wired (the wire passing hole 11 can be internally provided with the wire protecting plug), the temperature meter 82 can detect the temperature in the box 1 in real time through the thermocouple 84 and feed back the temperature to the temperature controller 81, so that the temperature controller 81 controls the heating pipe to work through the heating control module 83 so as to control the temperature in the box 1 in real time, meanwhile, in this embodiment, one end of the box 1 is further provided with the first position sensor 86, one end of the cover 3 is further provided with the second position sensor 87 matched with the first position sensor 86, and after the first position sensor 86 and the second position sensor 87 sense signals mutually after the cover 3 is covered, the background can control the heating pipe to work through the heating control module 83.

In one embodiment, the heat dissipation element 5 comprises a heat dissipation fan; an air inlet 12 communicated with the electric control box 8 is formed in one side, close to the electric control box 8, of the box body 1, and a cooling fan is arranged in the electric control box 8 and is arranged close to the air inlet 12; an air outlet 13 is further formed in one end, away from the air inlet 12, of the other side of the box body 1. When the heat dissipation and the temperature reduction are required to be carried out in the box body 1, the heat dissipation fan starts to work, and the heat dissipation air flow can be led into the box body 1 through the air inlet 12 by the heat dissipation fan and then flows out through the air outlet 13, so that the heat dissipation and the temperature reduction functions in the box body 1 are realized.

In an embodiment, a first guide cover 14 and a second guide cover 15 are respectively installed at the positions corresponding to the air inlet 12 and the air outlet 13 on the inner wall of the box body 1; the first guiding cover 14 is provided with an air inlet channel which is provided with an opening at one end and is communicated with the air inlet 12, and the second guiding cover 15 is provided with an air outlet channel which is provided with an opening at one end and is communicated with the air outlet 13. As shown in fig. 4, the opening of the air inlet channel and the opening of the air outlet channel are opened in opposite directions, and the air inlet channel and the air outlet channel are respectively arranged near one end of the box body 1, so that the flow direction of the heat dissipation air flow can be as shown by the arrow in fig. 4, the product can be quickly cooled, and the heat dissipation rate is improved; meanwhile, the air inlet 12 and the air outlet 13 can be covered by the first guide cover 14 and the second guide cover 15, so that the internal heat loss is reduced as much as possible in the heating process, the heating constant temperature effect is achieved, after the internal detection components are in a molten state when the temperature is finally raised, the tin point in the molten state is required to be solidified by rapid cooling, at the moment, the rapid cooling can be realized by the cooling fan under the action of the air inlet channel and the air outlet channel (after the air inlet 12 and the air outlet 13 are respectively provided with one guide cover, in the heating and constant temperature processes, no airflow change exists in the box 1, the purpose of heat preservation can be realized in the box 1, and when the heat is dissipated, the channel is formed by diagonal angle formation after the cooling fan is blown in, and the channel is similar to a wind tunnel, so that the cooling effect is very good once the cooling fan is opened.

In an embodiment, an annular clamping groove is formed in the top of the box body 1, and a sealing ring 16 is embedded in the annular clamping groove. After the cover 3 is covered, the sealing performance of the case 1 can be further improved by the seal ring 16.

The foregoing description of the preferred embodiment of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (10)

1. A heating in-situ apparatus for an X-ray inspection machine, comprising

The box body is internally provided with a bearing and clamping assembly which is at least used for bearing products and clamping and fixing the products;

the cover body is hinged with one side of the box body and is at least used for sealing the box body;

the heating piece is arranged on the cover body and is at least used for heating the inner space of the box body; the heat dissipation piece is arranged close to the box body and is at least used for dissipating heat and cooling the inner space of the box body.

2. The heated in-situ apparatus of an X-ray inspection machine of claim 1, wherein the load clamp assembly comprises a first rail, a second rail; the first guide rail and the second guide rail are arranged in the box body at intervals in parallel, the first guide rail is also connected with two first sliding blocks in a sliding manner, and the second guide rail is also connected with two second sliding blocks in a sliding manner; a limiting guide rail is also connected between each first sliding block and each second sliding block, and the two limiting guide rails are arranged in parallel at intervals; and two opposite sides of the two limit guide rails are respectively provided with a limit groove, and two ends of the product are respectively inserted into one limit groove for arrangement.

3. The heating in-situ apparatus of an X-ray inspection machine according to claim 2, wherein the two limit rails are also each slidably connected with a positioning clamp block, the positioning clamp blocks being at least used for clamping and fixing two sides of a product; and the positioning clamping block, the first sliding block and the second sliding block are also provided with locking knobs.

4. The heating in-situ apparatus of an X-ray inspection machine of claim 1, further comprising a base and a carrying frame; a first mounting groove is formed in the top of the base, and a carbon fiber bottom plate is further arranged in the first mounting groove; the carbon fiber bottom plate is provided with a first heat insulation plate, and the box body is arranged on the first heat insulation plate; the box body is provided with a first containing cavity with an opening at the top, and the inner wall of the first containing cavity is also provided with a second heat insulation plate; the bearing frame is arranged in the first accommodating cavity, and the outer wall of the bearing frame is clung to the second heat insulation plate; the bearing clamping assembly is arranged in the bearing frame.

5. The heating in-situ apparatus of an X-ray inspection machine of claim 1, wherein the cover comprises a rotary gland, a rotary hinge; the rotary gland is hinged with the upper part of one side of the box body through a rotary hinge; a third heat insulation plate is arranged on one side, close to the box body, of the rotary gland, and a first panel is further arranged on the third heat insulation plate; the heating element is arranged on the first panel; and the other side of the rotary gland is also provided with a carbon fiber pressing plate.

6. The heating in-situ apparatus of claim 5, wherein at least a first fixing block is mounted on one side of the first panel, and an arc-shaped slot is further formed on the first fixing block; the heating piece comprises a heating pipe which is clamped in the arc-shaped clamping groove; the first fixing block is further provided with a first compacting plate which is arranged on the heating pipe in a pressing mode and used for fixing the heating pipe in the arc-shaped clamping groove in a pressing mode.

7. The heating in-situ device of the X-ray inspection machine according to claim 1, wherein one side of the box body is also connected with an electric cabinet, one side of the box body is also provided with a wire passing hole penetrating into the electric cabinet, and a temperature controller, a temperature meter and a heating control module are also arranged in the electric cabinet; the heating control module is connected with the heating pipe, and the temperature controller is connected with the heating control module; the temperature instrument is connected with the temperature control module; and a thermocouple is also arranged in the box body and is connected with a thermometer.

8. The heating in-situ apparatus of an X-ray inspection machine of claim 7, wherein the heat sink comprises a heat dissipating fan; an air inlet communicated with the electric control box is formed in one side, close to the electric control box, of the box body, and a cooling fan is arranged in the electric control box and is arranged close to the air inlet; an air outlet is further formed in one end, away from the air inlet, of the other side of the box body.

9. The heating in-situ device of the X-ray inspection machine according to claim 8, wherein a first guide cover and a second guide cover are respectively arranged at the positions corresponding to the air inlet and the air outlet on the inner wall of the box body; the first guide cover is provided with an air inlet channel with an opening at one end and communicated with the air inlet, and the second guide cover is provided with an air outlet channel with an opening at one end and communicated with the air outlet.

10. The heating in-situ apparatus of an X-ray inspection machine according to claim 1, wherein the top of the box body is provided with an annular clamping groove, and a sealing ring is embedded in the annular clamping groove.