Experimental device and experimental method for water blocking and ablation characteristics of high-voltage cable buffer layer material
1. The high-voltage cable buffer layer material water-blocking and ablation characteristic experimental device is characterized by comprising a water-blocking test unit, an ablation test unit and a voltage loop unit;
the water blocking test unit (1) comprises a test water tank (11); the water tank (11) is provided with a water inlet, an exhaust port and a water outlet, and the water inlet is connected with the constant-pressure water supply assembly; the water tank is also provided with a test hole;
the ablation test unit comprises a vertical electrode column (21), a corrugated electrode plate (22), a grounding electrode plate (23), a horizontal electrode column (24) and a two-dimensional driving module; the buffer layer material is wound on the horizontal electrode column (24), one end of the vertical electrode column (21) is electrically connected with the voltage loop unit, the other end of the vertical electrode column is electrically connected and fixed with the corrugated electrode plate, the two-dimensional driving module drives the vertical electrode column (21) to move in two dimensions, so that the corrugated electrode plate (22) moves along the length direction of the horizontal electrode column (24) and the contact tightness between the corrugated electrode plate (22) and the buffer layer is adjusted; one end of the grounding electrode plate (23) is grounded, the other end of the grounding electrode plate is electrically connected with one end of the horizontal electrode column (24), and the other end of the horizontal electrode column (24) carries a buffer layer and extends into the water tank from the test hole through the sealing element;
the test of the water blocking and ablation characteristics of the high-voltage cable buffer layer material comprises the following specific steps:
step 1, opening an ablation test box (25), taking out a horizontal electrode column (24), tightly lapping a buffer layer material sample tape to the surface of the horizontal electrode column (24), wherein the lapping center distance is the width of the sample tape. Wrapping until the thickness of the sample is 2mm, and then bundling and fixing; the horizontal electrode column (24) is placed back into the ablation test box (25) and is well fixed with the grounding electrode slice (23) through threads;
step 2, inserting the horizontal electrode column (24) extending out of the ablation sample box and wrapping the sample belt, together with the ablation sample box, into a sample tube (15) of the test water tank; opening a sealing cover of the test water tank, sleeving a sealing gasket (16) on a horizontal electrode column (24) extending out of the sample tube (15), and sealing by using a sealing nut;
step 3, closing a sealing cover and a water outlet valve of the test water tank, opening a water inlet valve, a gas outlet valve and a water head tank, injecting deionized water with the temperature of (20 +/-10) DEG C into the test water tank within 5 minutes, and stopping injecting water when a water column in a water inlet pipe is 1m higher than the axis of a horizontal electrode column (24) by using a water level tester; closing the gas outlet valve during water injection; after the preset time of the test is reached, opening a water outlet valve to discharge test water, and measuring the penetration distance of the deionized water in the buffer material;
step 4, opening a worm gear reducer driving button, raising the height of the insulating supporting seat to a position where the corrugated electrode sheet (22) can flexibly move horizontally, and stopping; turning on a motor driving button, adjusting the insulating transverse rod to drive the vertical electrode column (21) to move, and moving to an insulating material drying area; a worm gear speed reducer driving button is turned on, the height of the insulating supporting seat is reduced, and the vertical electrode column (21) is driven to descend until the center of the corrugated electrode plate (22) is opposite to the center of the horizontal electrode column (24) and is pressed against the center of the corrugated electrode plate;
step 5, turning on a voltage source, raising the voltage slowly, stopping raising the voltage when a voltmeter shows that a preset test amplitude is reached, and recording the test process and parameter changes; when the continuous test reaches a preset time or open fire occurs and the numerical value of an ammeter is increased rapidly, the power supply is turned off;
and 6, repeating the step 4, respectively moving the corrugated electrode plate (22) to a damp part and a dry-wet junction, and carrying out a test according to the step 5 to obtain the ablation characteristics of the buffer layer materials in different areas under the condition that the inlet water is damp.
2. The experimental device for water blocking and ablation characteristics of the buffer layer material of the high-voltage cable according to claim 1, wherein the ablation test unit comprises an ablation test box (25), the ablation test box (25) is provided with a horizontal test groove, the horizontal electrode column (24) is located in the test groove, and one end of the test groove is communicated with the test hole through a sealing member.
3. The experimental device for water blocking and ablation characteristics of the high-voltage cable buffer layer material according to claim 1 or 2, wherein the two-dimensional driving module comprises a horizontal driving unit and a vertical driving unit; the horizontal driving unit is fixed with the output end of the vertical driving unit, and the output end of the vertical driving unit moves up and down; the output end of the horizontal driving unit horizontally reciprocates along the length direction of the horizontal electrode column (24); the upper end of the vertical electrode column (21) is fixed with the output end of the horizontal driving unit.
4. The experimental device for water blocking and ablation characteristics of high-voltage cable buffer layer materials according to claim 3, wherein the horizontal driving unit comprises a motor (273), a gear (272) and a cross bar (274); the cross bars (274) are made of insulating materials; the output shaft of the motor (273) is concentrically fixed with the gear (272); the lower surface of one end of the cross rod (274) is provided with a rack (272) meshed with a gear (271), and the vertical electrode column (21) of the cross rod (274) is vertically fixed with the cross rod (274); the gear (271) drives the cross rod (274) to move horizontally and drives the vertical electrode column (21) to move horizontally.
5. The experimental apparatus for water blocking and ablation properties of buffer layer material of high voltage cable according to claim 4, wherein the horizontal driving unit further comprises a supporting member; the upper surface of the support is provided with a ball (253), and the cross bar (274) is lapped on the ball (253) and is in rolling fit with the support.
6. The experimental device for water blocking and ablation characteristics of the high-voltage cable buffer layer material according to claim 1 or 2, wherein the sealing member comprises a sample tube (15), a nut; the sample tube (15) is provided with an external thread, the sample tube (15) penetrates through the test hole, and the sample tube (15) is clamped and fixed in the test hole through two nuts; the horizontal electrode column (24) carries the buffer layer to pass through the sample tube (15) to the experiment water tank.
7. The experimental device for water blocking and ablation characteristics of the buffer layer material of the high-voltage cable according to claim 6, wherein at least a sealing gasket (16) is sleeved on the tube body of the sample tube (15) in the test water tank (11), and the sealing gasket (16) is positioned between the nut and the wall of the water tank.
8. The experimental device for water blocking and ablation characteristics of the high-voltage cable buffer layer material as claimed in claim 1 or 2, wherein the constant-pressure water supply assembly comprises a water head tank (121), a water inlet pipe (122) and a water level detector (124); the water outlet of the water head tank (121) is communicated with the water inlet of the experimental water tank through a water inlet pipe (122), and a water inlet valve (123) is installed on the water inlet pipe (122); the water level detector (124) is installed in the head tank (121) to detect the water level of the inlet pipe (122).
9. The experimental device for water blocking and ablation characteristics of the high-voltage cable buffer layer material according to claim 1 or 2, wherein the voltage loop unit comprises a voltmeter (31), an ammeter (32), a fuse (33), a step-up transformer (34) and a voltage source (35); the voltage source (35) is connected with the fuse (33) in series and is connected to the input end of the step-up transformer (34); the output end of the step-up transformer (34) is connected with a voltmeter in parallel, and the two ends of the step-up transformer (34) after being connected with the ammeter (32) in series are respectively connected with a lead-out wire and a grounding wire of the vertical electrode column (21).
10. The experimental device for water blocking and ablation characteristics of the high-voltage cable buffer layer material as claimed in claim 1 or 2, further comprising a pressure sensor, wherein the pressure sensor is fixed at the air outlet.
Background
The acceleration of the urbanization process brings about the increase of the ground entering amount of the high-voltage cable and also aggravates the potential electric power safety risk. The buffer layer is an important component of the high-voltage cable, can effectively ensure the electrical contact between the aluminum sheath and the insulation shield, and solves the problem of the mismatch of the thermal expansion rates between the insulation part of the cable and the aluminum sheath. In addition, the buffer layer has water resistance, and the buffer layer can expand rapidly after absorbing water, fill the gap between the buffer layer and the corrugated aluminum sheath and prevent water from longitudinally permeating.
At present, special standards are lacked for standardizing the buffer layer materials, and cable manufacturers are difficult to determine the quality requirements during purchasing, so that the phenomenon of insufficient quality sometimes occurs, and the product difference among different manufacturers is large. In recent years, domestic power operation enterprises frequently find the phenomenon of ablation caused by discharge of a buffer layer of an operation cable, and the industry roughly proposes the reasons of ablation caused by concentration of capacitance and current, ablation caused by electrochemical corrosion, ablation caused by discharge of the buffer layer and an aluminum sheath, ablation caused by circulation of a metal sheath and the like. According to the reason analysis, the influence of structural factors of the cable is eliminated, and a large number of researches show that the white powder spots at the ablation part of the buffer layer are closely related to the water-blocking powder in the buffer layer, so that the resistance between the buffer layer and the metal sheath is increased, and the ablation is caused. The content and the type of the water-blocking powder determine the water-blocking performance, so that a contradiction relationship exists between the water-blocking performance and the ablation resistance of the buffer material. However, at present, most of the researches mainly aim at qualitative analysis, are provided with subjective colors, and are not verified experimentally.
In order to explore the internal relation between the water resistance performance and the ablation phenomenon of the high-voltage cable buffer layer material, the invention designs a test device and a test method for the water resistance and the ablation characteristics of the high-voltage cable buffer layer material, which aim to simulate the whole process of ablation when the cable is subjected to moisture as truly as possible and provide a technical scheme for evaluating the water resistance and the ablation resistance of the existing buffer layer material in the market.
Disclosure of Invention
The invention aims to solve the technical problem that a test device capable of truly simulating the whole ablation process when the cable is subjected to water inflow and moisture is absent in the prior art, and provides a test device for water blocking and ablation characteristics of a buffer layer material of a high-voltage cable, which can simultaneously test the water inflow test and the ablation characteristics of the buffer layer.
The invention solves the technical problems through the following technical means:
the high-voltage cable buffer layer material water-blocking and ablation characteristic experiment device comprises a water-blocking test unit, an ablation test unit and a voltage loop unit;
the water blocking test unit (1) comprises a test water tank (11); the water tank (11) is provided with a water inlet, an exhaust port and a water outlet, and the water inlet is connected with the constant-pressure water supply assembly; the water tank is also provided with a test hole;
the ablation test unit comprises a vertical electrode column (21), a corrugated electrode plate (22), a grounding electrode plate (23), a horizontal electrode column (24) and a two-dimensional driving module; the buffer layer material is wound on the horizontal electrode column (24), one end of the vertical electrode column (21) is electrically connected with the voltage loop unit, the other end of the vertical electrode column is electrically connected and fixed with the corrugated electrode plate, the two-dimensional driving module drives the vertical electrode column (21) to move in two dimensions, so that the corrugated electrode plate (22) moves along the length direction of the horizontal electrode column (24) and the contact tightness between the corrugated electrode plate (22) and the buffer layer is adjusted; one end of the grounding electrode slice (23) is grounded, the other end of the grounding electrode slice is electrically connected with one end of the horizontal electrode column (24), and the other end of the horizontal electrode column (24) carries the buffer layer and extends into the water tank from the test hole through the sealing piece.
The test of the water blocking and ablation characteristics of the high-voltage cable buffer layer material comprises the following specific steps:
step 1, opening an ablation test box (25), taking out a horizontal electrode column (24), tightly lapping a buffer layer material sample tape to the surface of the horizontal electrode column (24), wherein the lapping center distance is the width of the sample tape. Wrapping until the thickness of the sample is 2mm, and then bundling and fixing; the horizontal electrode column (24) is placed back into the ablation test box (25) and is well fixed with the grounding electrode slice (23) through threads;
step 2, inserting the horizontal electrode column (24) extending out of the ablation sample box and wrapping the sample belt, together with the ablation sample box, into a sample tube (15) of the test water tank; opening a sealing cover of the test water tank, sleeving a sealing gasket (16) on a horizontal electrode column (24) extending out of the sample tube (15), and sealing by using a sealing nut;
step 3, closing a sealing cover and a water outlet valve of the test water tank, opening a water inlet valve, a gas outlet valve and a water head tank, injecting deionized water with the temperature of (20 +/-10) DEG C into the test water tank within 5 minutes, and stopping injecting water when a water column in a water inlet pipe is 1m higher than the axis of a horizontal electrode column (24) by using a water level tester; closing the gas outlet valve during water injection; after the preset time of the test is reached, opening a water outlet valve to discharge test water, and measuring the penetration distance of the deionized water in the buffer material;
step 4, opening a worm gear reducer driving button, raising the height of the insulating supporting seat to a position where the corrugated electrode sheet (22) can flexibly move horizontally, and stopping; turning on a motor driving button, adjusting the insulating transverse rod to drive the vertical electrode column (21) to move, and moving to an insulating material drying area; a worm gear speed reducer driving button is turned on, the height of the insulating supporting seat is reduced, and the vertical electrode column (21) is driven to descend until the center of the corrugated electrode plate (22) is opposite to the center of the horizontal electrode column (24) and is pressed against the center of the corrugated electrode plate;
step 5, turning on a voltage source, raising the voltage slowly, stopping raising the voltage when a voltmeter shows that a preset test amplitude is reached, and recording the test process and parameter changes; when the continuous test reaches a preset time or open fire occurs and the numerical value of an ammeter is increased rapidly, the power supply is turned off;
and 6, repeating the step 4, respectively moving the corrugated electrode plate (22) to a damp part and a dry-wet junction, and carrying out a test according to the step 5 to obtain the ablation characteristics of the buffer layer materials in different areas under the condition that the inlet water is damp.
Further, the ablation test unit comprises an ablation test box (25), a horizontal test groove is formed in the ablation test box (25), the horizontal electrode column (24) is located in the test groove, and one end of the test groove is communicated with the test hole through a sealing piece.
Further, the two-dimensional driving module comprises a horizontal driving unit and a vertical driving unit; the horizontal driving unit is fixed with the output end of the vertical driving unit, and the output end of the vertical driving unit moves up and down; the output end of the horizontal driving unit horizontally reciprocates along the length direction of the horizontal electrode column (24); the upper end of the vertical electrode column (21) is fixed with the output end of the horizontal driving unit.
Further, the horizontal driving unit comprises a motor (273), a gear (272), and a cross bar (274); the cross bars (274) are made of insulating materials; the output shaft of the motor (273) is concentrically fixed with the gear (272); the lower surface of one end of the cross rod (274) is provided with a rack (272) meshed with a gear (271), and the vertical electrode column (21) of the cross rod (274) is vertically fixed with the cross rod (274); the gear (271) drives the cross rod (274) to move horizontally and drives the vertical electrode column (21) to move horizontally.
Further, the horizontal driving unit further comprises a support; the upper surface of the support is provided with a ball (253), and the cross bar (274) is lapped on the ball (253) and is in rolling fit with the support.
Further, the seal comprises a sample tube (15), a nut; the sample tube (15) is provided with an external thread, the sample tube (15) penetrates through the test hole, and the sample tube (15) is clamped and fixed in the test hole through two nuts; the horizontal electrode column (24) carries the buffer layer to pass through the sample tube (15) to the experiment water tank.
Furthermore, at least a sealing gasket (16) is sleeved on the pipe body of the sample pipe (15) in the test water tank (11), and the sealing gasket (16) is positioned between the nut and the wall of the water tank.
Further, the constant-pressure water supply assembly comprises a water head tank (121), a water inlet pipe (122) and a water level detector (124); the water outlet of the water head tank (121) is communicated with the water inlet of the experimental water tank through a water inlet pipe (122), and a water inlet valve (123) is installed on the water inlet pipe (122); the water level detector (124) is installed in the head tank (121) to detect the water level of the inlet pipe (122).
Further, the voltage loop unit comprises a voltmeter (31), an ammeter (32), a fuse (33), a step-up transformer (34) and a voltage source (35); the voltage source (35) is connected with the fuse (33) in series and is connected to the input end of the step-up transformer (34); the output end of the step-up transformer (34) is connected with a voltmeter in parallel, and the two ends of the step-up transformer (34) after being connected with the ammeter (32) in series are respectively connected with a lead-out wire and a grounding wire of the vertical electrode column (21).
Further, the exhaust system also comprises a pressure sensor, and the pressure sensor is fixed at the exhaust port.
The invention has the advantages that:
(1) the test device for testing the water resistance and ablation characteristics of the high-voltage cable buffer layer material can simultaneously perform water resistance performance test and ablation phenomenon simulation of the buffer layer material, and conforms to the ablation process of the buffer layer after the cable is wetted by water.
(2) Through turbine lead screw elevation structure and gear (271), rack (272) structure, realize the displacement of remote control ripple electrode piece (22) on the buffer layer sample, realize the regional ablation test of the different degrees of wetting of buffer material, it is more meticulous to the aassessment of its performance. All adopt the insulating part to carry out electrical isolation between worm gear speed reducer, motor and the high pressure, the safety in utilization is high.
The device has simple and reliable structure, can realize the evaluation of the water resistance and the ablation resistance of the buffer material, researches the ablation mechanism caused by the electrochemical corrosion of the buffer material after the cable is filled with water, and reveals the internal relation between the water resistance and the ablation phenomenon of the buffer material.
Drawings
Fig. 1 is a schematic view of a device for testing water blocking and ablation properties of a buffer layer material of a high-voltage cable according to an embodiment of the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
As shown in fig. 1, the present embodiment provides a testing apparatus for testing water blocking and ablation properties of a buffer layer material of a high voltage cable, which includes a water blocking testing unit 1 for evaluating water blocking performance of the buffer layer, an ablation testing unit 2 for simulating ablation phenomenon in a water inlet area of the buffer layer, and a voltage loop unit 3 for providing electric energy.
The water-blocking test unit 1 comprises a test water tank 11, a constant pressure water supply assembly for providing constant water pressure, an exhaust pipe 13 for exhausting gas in the tank, an outlet pipe 14 for exhausting test water, a sample pipe 15, a sealing gasket 16 for sealing a buffer layer material and a sealing screw 17.
The test water tank 11 is of a three-dimensional structure, the bottom of the test water tank is an insulating rubber plate, and the top of the test water tank is provided with a sealing cover 121.
The constant pressure water supply assembly comprises a water head tank 121, a water inlet pipe 122, a water inlet valve 123 and a water level detector 124; the water inlet pipe 122 is a glass pipe with the inner diameter larger than 10mm, the upper end of the water inlet pipe is connected with the water head tank 121, the lower end of the water inlet pipe is connected with the water inlet of the test water tank 11, and the middle of the pipe is provided with a water inlet valve 123; the water inlet valve 123 controls deionized water to be injected into the test water tank 11; the water level detector 124 is an ultrasonic probe for detecting the depth of the deionized water level in the test water tank 11.
An exhaust valve 131 is arranged in the exhaust pipe 13 and used for exhausting gas in the test water tank 11 during experiment water injection and maintaining the test air pressure stable. The exhaust valve 131 is generally a solenoid valve, which is convenient to control. In order to control the pressure, the present embodiment also mounts a pressure sensor on the exhaust pipe 13. The water level detector 124, the water inlet valve 123, the exhaust valve 131 and the pressure sensor are respectively in communication connection with the controller. The controller controls the opening and closing of the water inlet valve 123 and the exhaust valve 131 according to the current water level and the pressure in the pipeline, so that the purpose of constant-pressure water supply is achieved.
And the water outlet pipe 14 is arranged at the bottom of the test water tank 11 at the opposite side of the ablation test unit, and a water outlet valve 141 is arranged in the water outlet pipe.
The sample tube 15 is detachably and fixedly connected in an experimental hole in the side wall of the test water tank 11, the ablation test box 25 is provided with a horizontal test groove, the horizontal electrode column 24 is positioned in the test groove, and one end of the test groove is communicated with the experimental hole. The sample tube 15 has an external thread, and the sample tube 15 is fixed in the test hole by internal and external clamping of two nuts. At least one sealing gasket 16 is arranged between the wall of the experimental water tank 11 and the nut, and the sealing gaskets 16 can be arranged on the inner section and the outer section of the sample tube 15 for sealing effect. The nut provides pressure to the gasket 16 to cause the gasket 16 to seal substantially with the sample and the sample tube 15. The gasket 16 is typically a rubber ring. The horizontal electrode column 24 carries the buffer layer from the sample tube 15 through into the test water tank 11, with the ends of the horizontal electrode column and buffer layer exposed to the water. Here, the buffer layer and the sample tube are sealed by filling the gap between the buffer layer and the sample tube after the buffer layer in the experimental water tank is soaked in water, so as to prevent water from penetrating along the length direction of the horizontal electrode column.
The ablation test unit comprises a vertical electrode column 21, a corrugated electrode plate 22, a grounding electrode plate 23, a horizontal electrode column 24, an ablation test box 25, a vertical motion module and a horizontal motion module; the buffer layer material is wound on the horizontal electrode column 24, and the vertical motion module and the horizontal motion module control the vertical electrode column 21 to move up and down and in parallel.
The horizontal motion module comprises a gear 271, a rack 272, a motor 273 and an insulating cross bar 274; the output shaft of the motor 273 is coaxially and fixedly connected with the gear 271, and the gear 271 can keep meshed with the rack 272 when rotating; the insulating rail 274 is fixedly connected to the rack 272, and the rack may be provided on the lower surface of the insulating rail 274. The insulating rails 274 are vertically connected to the vertical electrode column 21; the tail end of the vertical electrode column 21 is fixedly connected with the corrugated electrode plate 22, and the head end is connected with the voltage loop unit through an electric wire and an insulating groove box 275 outside the ablation test box 25. The supporting member includes a supporting base 251 and a supporting plate 252, the motor 273 is fixed on the supporting base 251, and the supporting plate 251 is fixed on the supporting base 251 by a vertical rod. The supporting base 251 and the supporting plate 252 are made of an insulating material. The supporting plate 252 has a slot hole in the center through which the vertical electrode column 21 passes. The balls 253 are arranged on two sides of the slotted hole of the supporting plate 252, and the insulating cross bar 274 is carried on the balls 253 to assist the parallel movement of the vertical electrode columns 21. Correspondingly, the upper surface of the ablation test chamber 25 is also provided with a groove for moving the vertical electrode column 21.
The vertical motion module adopts a turbine screw lifting structure and comprises a worm gear reducer 261, a worm 262, a worm wheel 263, a lifting screw 264, an insulating support base 265, an insulating shell 266 and the like. The worm reducer drives the worm to rotate, and the transmission enables the worm to reduce the speed. The center of the turbine adopts an internal thread structure to drive the lifting screw rod to move linearly up and down. The elevating screw is fixedly connected with the supporting base 251 so as to support the whole horizontal movement module and drive the horizontal movement module to move up and down.
A semi-cylindrical buffer material groove is arranged in the ablation test box 25, the buffer material groove, the horizontal electrode column 24 and the sample tube are concentric, and the radius of the buffer material groove is consistent with that of the corrugated electrode plate 22. The grounding electrode plate 23 is embedded in the side wall of the ablation test box 25, is generally positioned at one side far away from the experimental water tank 11, is in threaded connection with the horizontal electrode column 24, and is grounded at the back side through a grounding wire;
the voltage loop unit comprises a voltmeter 31, an ammeter 32, a fuse 33, a step-up transformer 34 and a voltage source 35. The voltage source 35 is connected with the fuse 33 in series and is connected to the input end of the step-up transformer 34; the output end of the step-up transformer 34 is connected in parallel with the voltmeter 31, and both ends of the output end of the step-up transformer are respectively connected with the lead-out wire and the grounding wire of the vertical electrode pole 21 after being connected in series with the ammeter 32.
In this embodiment, the test water tank, the sample tube, and the seal screw are all made of epoxy resin. The test water tank and the ablation test tank 25 are mounted on the same insulating base. The motor and the worm gear reducer are respectively connected into a first driving switch and a second driving switch which are arranged on the outer wall of the ablation test box 25 through electric wires.
The radius of the section of the horizontal electrode column 24 is 58 mm; the corrugated electrode sheet 22 is a single pitch of aluminum, the pitch length is 14mm, the trough radius is 60.5mm, the embossing depth is 4mm, and the thickness is 1.5 mm.
The test device for testing the water resistance and ablation characteristics of the buffer layer material of the high-voltage cable designed by the embodiment can simultaneously test the water resistance performance and simulate the ablation phenomenon of the buffer layer material, and accords with the ablation process of the buffer layer after the cable is wetted by water.
Through turbine lead screw elevation structure and gear 271 rack 272 structure, realize the displacement of remote control ripple electrode piece 22 on the buffer layer sample, realize the regional ablation test of the different degrees of weiding of buffer material, it is more meticulous to the aassessment of its performance. All adopt the insulating part to carry out electrical isolation between worm gear speed reducer, motor and the high pressure, the safety in utilization is high.
Corresponding to the device, the invention also provides a method for testing the water resistance and ablation characteristics of the high-voltage cable buffer layer material, which is used for testing the water resistance and ablation characteristics of the high-voltage cable buffer layer material and comprises the following specific steps:
step 1, opening an ablation test box 25, taking out a horizontal electrode column 24, and tightly wrapping a buffer layer material sample tape to the surface of the horizontal electrode column 24, wherein the wrapping center distance is the width of the sample tape. And (5) wrapping until the thickness of the sample is 2mm, and then bundling and fixing. The horizontal electrode column 24 is placed back into the ablation test box 25 and is well fixed with the grounding electrode slice 23 through threads;
and 2, inserting the horizontal electrode column 24 extending out of the ablation sample box and wrapping the sample belt, together with the ablation sample box, into a sample tube of the test water tank. Opening a sealing cover of the test water tank, sleeving a sealing gasket on the position of the horizontal electrode column 24 extending out of the sample tube, and sealing and fixing the sealing gasket by using a sealing nut;
and 3, closing the sealing cover and the water outlet valve of the test water tank, opening the water inlet valve, the air outlet valve and the water head tank, injecting deionized water with the temperature of 20 +/-10 ℃ into the test water tank within 5 minutes, and stopping injecting water when the water column in the water inlet pipe is controlled to be 1m higher than the axis of the 24 horizontal electrode columns by using the water level detector. And closing the gas outlet valve during water injection. After the preset time of the test is reached, opening a water outlet valve to discharge test water, and measuring the penetration distance of the deionized water in the buffer material;
and 4, opening a worm gear speed reducer driving button, and lifting the height of the insulating supporting seat to a position where the corrugated electrode sheet 22 can flexibly and horizontally move and then stopping. And turning on a motor driving button, adjusting the insulating transverse rod to drive the vertical electrode column 21 to move, and moving to an insulating material drying area. A worm gear speed reducer driving button is turned on, the height of the insulating supporting seat is reduced, and the vertical electrode column 21 is driven to descend until the centers of the corrugated electrode plate 22 and the horizontal electrode column 24 are opposite to and pressed against each other;
and 5, opening a voltage source, raising the voltage slowly, stopping raising the voltage when the voltmeter shows that the preset amplitude of the test is reached, and recording the test process and the parameter change. When the continuous test reaches a preset time or open fire occurs and the numerical value of an ammeter is increased rapidly, the power supply is turned off;
and 6, repeating the step 4, respectively moving the corrugated electrode plate 22 to the affected part and the dry-wet junction, and carrying out the test according to the step 5 to obtain the ablation characteristics of the buffer layer materials in different areas under the condition that the inlet water is affected with damp.
The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.
- 上一篇:石墨接头机器人自动装卡簧、装栓机
- 下一篇:一种经济快捷渗透系数确定方法及装置