CN212059993U - In-situ stress corrosion test device for X-ray microscope - Google Patents

In-situ stress corrosion test device for X-ray microscope Download PDF

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Publication number
CN212059993U
CN212059993U CN202020868508.4U CN202020868508U CN212059993U CN 212059993 U CN212059993 U CN 212059993U CN 202020868508 U CN202020868508 U CN 202020868508U CN 212059993 U CN212059993 U CN 212059993U
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loading screw
screw rod
tension
motor
stress corrosion
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范国华
唐光泽
金俊阳
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Nanjing Yingwo Technology Co ltd
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Nanjing Libian Instrument Co ltd
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Abstract

The invention provides an in-situ stress corrosion test device for an X-ray microscope, which comprises a tension device and a corrosive liquid container, wherein the tension device is placed in the corrosive liquid container; the tension device comprises a motor, an upper support, a base, a loading screw rod and a tension frame, an output shaft of the motor is connected with the loading screw rod, the loading screw rod is fixedly connected with the tension frame, an upper clamp is fixed at the bottom of the tension frame, and a lower clamp is integrally formed on the upper surface of the base. According to the invention, through the matching of the loading screw rod, the tension frame and the upper and lower clamps, the tension loaded on the sample to be tested can be continuously adjusted, meanwhile, through the matching of the pressure sensor and the motor, the actual load on the sample to be tested is equal to the preset target load, and the device has a small volume and meets the use requirement of the X-ray microscope.

Description

In-situ stress corrosion test device for X-ray microscope
Technical Field
The invention relates to stress corrosion test equipment, in particular to an in-situ stress corrosion test device for an X-ray microscope.
Background
Stress corrosion refers to the corrosion acceleration behavior of a material under the combined action of tensile stress and a corrosion medium, and accidents caused by the stress corrosion are usually not predicted in advance, so that disastrous results such as chemical equipment explosion, oil field pipeline breakage and the like can be caused. Although researchers have conducted extensive research into the behavior of stress corrosion of materials, there are many problems to be clarified regarding the mechanism and process of stress corrosion of different materials.
X-ray microscopy is an emerging material analysis testing technique that can perform non-destructive analysis of the internal structure and crystal orientation distribution of a material through absorption and diffraction of X-rays by the material. Through the development of some in-situ experiment accessories, the service behavior of the material under the environment action can be researched in situ in real time by using an X-ray microscope, the characteristics of the material can be more accurately understood and known, and more bases are provided for the reasonable use of the material and the development of new materials. There is no commercial X-ray microscope attachment available to perform in situ stress corrosion studies.
Due to the limitation of the power of the X-ray source of the X-ray microscope, the distance between the X-ray source and the detector is short, and the space for placing accessories is limited. Meanwhile, in order to obtain a high signal-to-noise ratio and improve the definition and resolution of an imaging effect, the distance between the X-ray source and the detector is required to be as close as possible. Miniaturization is an important requirement and key technical feature of an X-ray microscope in-situ stress corrosion device. The invention provides a small in-situ stress corrosion research device which can be used for an X-ray microscope.
Disclosure of Invention
In order to overcome the defects of the conventional in-situ stress corrosion equipment, the invention provides an in-situ stress corrosion test device for an X-ray microscope.
The technical solution for realizing the purpose of the invention is as follows:
an in-situ stress corrosion test device for an X-ray microscope comprises a tension device and a corrosive liquid container, wherein the tension device is placed in the corrosive liquid container, and corrosive solution is filled in the corrosive liquid container; the tension device comprises a motor, an upper bracket, a base, a loading screw rod and a tension frame, wherein the upper bracket comprises a top panel, a bottom panel and a back panel, and the top panel and the bottom panel are fixedly connected through the back panel; the motor is arranged above the top panel, a speed reducer is arranged on an output shaft of the motor, the output shaft of the motor is connected with the loading screw rod through a coupler, the loading screw rod penetrates through the top panel and extends into the bottom panel, the loading screw rod can rotate along the axis and move along the axial direction, and the bottom panel and the base are connected through a supporting cylinder to form a cavity; the loading screw rod is fixedly connected with the tension frame, the tension frame moves along the axial direction along with the loading screw rod, the tension frame penetrates through the bottom panel and extends into the cavity, an upper clamp is fixed at the bottom of the tension frame, a first clamping groove used for clamping a sample to be tested is formed in the lower surface of the upper clamp, a lower clamp is integrally formed on the upper surface of the base, a second clamping groove used for clamping the sample to be tested is formed in the upper surface of the lower clamp, and the second clamping groove is vertically opposite to the first clamping groove.
Furthermore, the in-situ stress corrosion test device for the X-ray microscope is characterized in that an upper positioning sliding bearing and a lower positioning sliding bearing are respectively arranged in the top panel and the bottom panel of the upper support and are respectively used for limiting the axial displacement of the loading screw rod.
Furthermore, the in-situ stress corrosion test device for the X-ray microscope further comprises a pressure sensor, wherein the pressure sensor is arranged between the tail end of the loading screw rod and the bottom panel of the upper bracket and is connected with the controller of the motor.
Furthermore, the in-situ stress corrosion test device for the X-ray microscope is characterized in that the supporting cylinder is made of carbon fiber, ultra-high molecular weight polyethylene or polytetrafluoroethylene and the like with low X-ray absorption rate.
Compared with the prior art, the invention adopting the technical scheme has the following technical effects:
the in-situ stress corrosion test device for the X-ray microscope realizes continuous adjustment of the tension loaded on the sample to be tested through the matching of the loading screw rod, the tension frame and the upper and lower clamps, simultaneously realizes the equality of the actual load on the sample to be tested and the preset target load through the matching of the pressure sensor and the motor, has small volume, and meets the use requirement of the X-ray microscope.
Drawings
FIG. 1 is a front view of the overall structure of the in-situ stress corrosion test apparatus for an X-ray microscope according to the present invention.
FIG. 2 is a left side view of the overall structure of the in-situ stress corrosion testing apparatus for an X-ray microscope according to the present invention.
Reference signs mean: 1. the testing device comprises a motor, 2, a coupler, 3, a connecting nut, 4, an upper positioning sliding bearing, 5, a loading screw rod, 6, an upper bracket, 61, a top panel, 62, a back panel, 63, a bottom panel, 7, a lower positioning sliding bearing, 8, a pressure sensor, 9, a tension frame, 10, an upper clamp, 101, a first clamping groove, 11, a supporting cylinder, 111, a cavity, 12, a base, 121, a lower clamp, 122, a second clamping groove, 13 and a corrosive liquid container, and 14 is a sample to be tested.
Detailed Description
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.
An in-situ stress corrosion test device for an X-ray microscope is shown in figures 1 and 2 and comprises a tension device and a corrosion liquid container 13, wherein the tension device is placed in the corrosion liquid container 13, and a corrosion solution is filled in the corrosion liquid container 13.
The tension device comprises a motor 1, an upper bracket 6, a base 12, a loading screw rod 5 and a tension frame 9. The upper bracket 6 comprises a top panel 61, a bottom panel 63 and a back panel 62, wherein the top panel 61 and the bottom panel 63 are fixedly connected through the back panel 62.
Motor 1 installs in top panel 61 top, and is equipped with a reduction gear on motor 1's the output shaft, motor 1's output shaft pass through shaft coupling 2 with loading screw 5 connects, loading screw 5 passes top panel 61 and stretches into to bottom surface board 63 in, and loading screw 5 can follow the axle center and rotate and along axial motion, is equipped with pressure sensor 8 between the terminal of loading screw 5 and the bottom surface board of upper bracket 6, and pressure sensor 8 is connected with motor 1's controller. An upper positioning sliding bearing 4 and a lower positioning sliding bearing 7 are respectively arranged in the top panel and the bottom panel of the upper bracket 6 and are respectively used for limiting the axial displacement of the loading screw 5.
The bottom panel 63 and the base 12 are connected by a support tube 11 to form a cavity 111, and the support tube 11 is made of carbon fiber, ultra-high molecular weight polyethylene or polytetrafluoroethylene with low X-ray absorption rate. The loading screw 5 is fixedly connected with a tension frame 9, and the tension frame 9 moves along the axial direction along with the loading screw 5. The tensile frame 9 penetrates through the bottom panel 63 and extends into the cavity 111, an upper clamp 10 is fixed at the bottom of the tensile frame 9, a first clamping groove 101 used for clamping a sample 14 to be tested is formed in the lower surface of the upper clamp 10, a lower clamp 121 is integrally formed on the upper surface of the base 12, a second clamping groove 122 used for clamping the sample 14 to be tested is formed in the upper surface of the lower clamp 121, and the second clamping groove 122 is vertically opposite to the first clamping groove 101.
The working principle of the in-situ stress corrosion test device for the X-ray microscope is as follows:
the motor 1 is used for providing tensile force of a tensile experiment, drives the loading screw rod 5 to rotate through the coupler 2, enables the tensile force frame 9 to move upwards through spiral transmission, and then drives the upper clamp 10 to realize loading on a sample 14 to be tested. The loading screw 5 is limited in its axial displacement by an upper positioning slide bearing 4 and a lower positioning slide bearing 7, between which the loading screw 5 can rotate and move in the axial direction.
In the process of a tensile experiment, the tension frame 9 provides a reaction force with the same magnitude for the loading screw 5, and the bottom of the loading screw 5 is supported by the pressure sensor 8, so that the magnitude of the tension applied to the sample 14 to be tested is equal to the magnitude of the pressure applied to the pressure sensor 8. The loading of the motor 1 is controlled by the pressure signal fed back by the pressure sensor 8 until the actual load of the sample 14 to be measured is equal to the preset target load. The supporting cylinder 1 is a frame connecting the upper bracket 6 and the base 12, and the supporting cylinder 11 is made of carbon fiber, ultra-high molecular weight polyethylene or polytetrafluoroethylene with low X-ray absorption rate.
The tensile device is placed in the corrosive liquid container 13, then the whole test device is placed on an X-ray microanalyzer test bed, and the experimental corrosive solution is injected into the corrosive liquid container 13 in the experimental process.
The foregoing is directed to embodiments of the present invention and, more particularly, to a method and apparatus for controlling a power converter in a power converter, including a power converter, a power.

Claims (4)

1. The in-situ stress corrosion test device for the X-ray microscope is characterized by comprising a tension device and a corrosion liquid container (13), wherein the tension device is placed in the corrosion liquid container (13), and a corrosion solution is filled in the corrosion liquid container (13);
the tension device comprises a motor (1), an upper bracket (6), a base (12), a loading screw rod (5) and a tension frame (9), wherein the upper bracket (6) comprises a top panel (61), a bottom panel (63) and a back panel (62), and the top panel (61) and the bottom panel (63) are fixedly connected through the back panel (62); the motor (1) is arranged above the top panel (61), a speed reducer is arranged on an output shaft of the motor (1), the output shaft of the motor (1) is connected with the loading screw rod (5) through a coupler (2), the loading screw rod (5) penetrates through the top panel (61) and extends into the bottom panel (63), the loading screw rod (5) can rotate along the axis and move along the axial direction, and the bottom panel (63) and the base (12) are connected through a supporting cylinder (11) to form a cavity (111);
the loading screw rod (5) is fixedly connected with a tension frame (9) externally, the tension frame (9) moves along the axial direction along with the loading screw rod (5), the tension frame (9) penetrates through a bottom panel (63) and extends into the cavity (111), an upper clamp (10) is fixed at the bottom of the tension frame (9), a first clamping groove (101) used for clamping a sample (14) to be tested is formed in the lower surface of the upper clamp (10), a lower clamp (121) is integrally formed on the upper surface of the base (12), a second clamping groove (122) used for clamping the sample (14) to be tested is formed in the upper surface of the lower clamp (121), and the second clamping groove (122) is opposite to the first clamping groove (101) in the vertical direction.
2. The in-situ stress corrosion test device for an X-ray microscope according to claim 1, wherein an upper positioning sliding bearing (4) and a lower positioning sliding bearing (7) are respectively arranged in the top panel and the bottom panel of the upper bracket (6) and are respectively used for limiting the axial displacement of the loading screw rod (5).
3. The in-situ stress corrosion test device for the X-ray microscope according to claim 1, further comprising a pressure sensor (8), wherein the pressure sensor (8) is arranged between the tail end of the loading screw (5) and the bottom panel of the upper bracket (6), and the pressure sensor (8) is connected with a controller of the motor (1).
4. The in-situ stress corrosion testing apparatus for an X-ray microscope according to claim 1, wherein the supporting cylinder (11) is made of carbon fiber, ultra-high molecular weight polyethylene or polytetrafluoroethylene, which has low X-ray absorption.
CN202020868508.4U 2020-05-22 2020-05-22 In-situ stress corrosion test device for X-ray microscope Active CN212059993U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111413360A (en) * 2020-05-22 2020-07-14 南京力变仪器有限公司 In-situ stress corrosion test device for X-ray microscope

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111413360A (en) * 2020-05-22 2020-07-14 南京力变仪器有限公司 In-situ stress corrosion test device for X-ray microscope

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Effective date of registration: 20220531

Address after: 210000 room 360-7, floor 3, building B, No. 116 Shiyang Road, Qinhuai District, Nanjing, Jiangsu Province

Patentee after: Nanjing yingwo Technology Co.,Ltd.

Address before: 210000 room 1952, hatching Eagle building, No. 99, Tuanjie Road, yanchuang Park, China (Jiangsu) pilot Free Trade Zone, Pukou District, Nanjing, Jiangsu Province

Patentee before: Nanjing Libian Instrument Co.,Ltd.