CN203965524U - A kind of solid dielectric material trap parameters acquisition system - Google Patents
A kind of solid dielectric material trap parameters acquisition system Download PDFInfo
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- CN203965524U CN203965524U CN201420518081.XU CN201420518081U CN203965524U CN 203965524 U CN203965524 U CN 203965524U CN 201420518081 U CN201420518081 U CN 201420518081U CN 203965524 U CN203965524 U CN 203965524U
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Abstract
The utility model discloses a kind of solid dielectric material trap parameters acquisition system, comprise constant temperature oven and be arranged on three electrode corona charging systems, surface potential measurement system, rotary support system and the temperature control system in constant temperature oven; Three electrode corona charging systems comprise the multistylus electrode of coaxial setting from top to bottom and the rosette electrode of ground connection; Surface potential measurement system comprises the condenser type static probe being arranged on adjusting insulation fixed mount; Rotary support system comprises insulating carriage, and the upper surface of metal aluminum sheet is provided with metal rotary disk, has METAL HEATING PROCESS box; Temperature control system comprises first heater and secondary heating mechanism.The utility model can carry out the trap level of solid dielectric material and the collection of trap density parameter in ground, there is feature applied widely, measuring accuracy is high, simple to operation, for Solid Dielectric Surface electrification phenomenon and to the research of the aspects such as edge flashing performance impact, provide a kind of effective analysis means.
Description
Technical field
The utility model relates to a kind of insulating material dielectric properties proving installation, relates in particular to a kind of solid dielectric material trap parameters acquisition system.
Background technology
At present, insulating material of polymer and oil immersion insulation is used widely in electric insulation field because of its good dielectric properties.But along with the raising of voltage class of electric power system and the development of HVDC Transmission Technology, the space charge effect problem of polymer insulation is outstanding day by day, cause thus the distortion of polymeric material internal electric field, cause shelf depreciation and electric branch development, thereby cause material aging and failure of insulation problem, how to suppress and the space charge eliminated in insulation has become the study hotspot in domestic and international electric insulation field.
At present a lot of about the research of polymkeric substance agine mechaism, wherein more representational is the thermoelectron initiated polymerization thing degraded theory of people's propositions such as Tu Demin of Canadian Gao Guanzhi (Kwan-Chi Kao) and domestic Xi'an Communications University.Under high electric field action, electrons is by during Schottky effect (Schottky effect) or Fowler-Nordheim effect (Fowler-Nordheim effect) are from electrode injection to polymkeric substance, owing to having a large amount of trap states in the energy gap of material forbidden band, therefore the mean free path of electrons is short, is captured very soon and form space charge by trap.Entering of space charge sunken/recombination process in, when electric charge moves to low-energy state by high-energy state, unnecessary energy is transferred to another electronics by non-radiative form, makes the latter become thermoelectron.The thermoelectron with enough energy will cause molecular degradation and forms a large amount of macromolecular radicals, will further cause free chain reaction, causes the further degraded of polymkeric substance.Thermionic generation and thermionic energy are decided by density and the degree of depth of trap, change trap depth or the density of polymkeric substance, just can change thermionic formation probability and energy.Therefore measure and the Trap Characteristics of analysis of material as energy level, density etc., for the space charge of material, form and the ageing state that suppresses mechanism and polymeric material characterizes and assesses tool and is of great significance.
On the other hand, in embedded-type electric electrode systems, near trapped charge electrode injects, transports, compound and desorption process also can be to edge flashing phenomenon generation material impact.Dielectric Trap Characteristics and surface charging characteristic are subject to extensive concern for a long time always, think that the surface flashover characteristics of medium is closely related under itself and vacuum condition.
Based on above-mentioned analysis, Trap Characteristics affects dielectric and the flash-over characteristic of solid dielectric material very significantly, and may become a kind of solid dielectric material property characterization parameter of more intrinsic, the trap parameters tool of therefore measuring and analyze solid insulating material is of great significance.Current domestic researchist generally obtains decay current by measuring isothermal surface potential decay, and then obtains the trap information of material surface.But most measuring systems all exist, system charging effect is inhomogeneous, charge injection is insufficient, survey record needs the problems such as manual operation, thereby has caused that measurement result is dispersed large, the result such as poor repeatability, precision are low.
About surface potential measurement and record, mostly adopt uniformly-spaced time manual type record at present, expend time in, record not accurate enough.Most measuring systems, after completing corona charging, need manually needle point to be replaced by current potential probe measurement surface potential decay, the time that this process need is longer, are difficult to measure the transient potential information after having charged.
Charge injection is the key of Measurement accuracy material Trap Characteristics fully, and solid dielectric material require could obtain charge injection comparatively fully under higher temperature (different because of material, to be generally 60~80 ℃).Existing test macro does not have heating condition, is difficult to realize the preheating of solid dielectric material, has a strong impact on experiment effect.
Utility model content
The purpose of this utility model is to provide a kind of solid dielectric material trap parameters acquisition system, can carry out the trap level of solid dielectric material and the collection of trap density parameter in ground, there is feature applied widely, measuring accuracy is high, simple to operation.
The utility model adopts following technical proposals:
A solid dielectric material trap parameters acquisition system, comprises constant temperature oven and is arranged on three electrode corona charging systems, surface potential measurement system, rotary support system and the temperature control system in constant temperature oven;
Three described electrode corona charging systems comprise the multistylus electrode of coaxial setting from top to bottom and the rosette electrode of ground connection, multistylus electrode connects DC charging power supply, the upper surface of rosette electrode is used for placing sample to be tested, and rosette electrode comprises copper electrode and the aluminium electrode of contact up and down and eccentric setting;
Described surface potential measurement system comprises the condenser type static probe being arranged on adjusting insulation fixed mount, and the output terminal of condenser type static probe connects signal conditioning circuit and the signal acquisition circuit outside constant temperature oven successively;
Described rotary support system comprises the insulating carriage that the upper surface that is arranged in constant temperature oven is metal aluminum sheet, the upper surface of metal aluminum sheet is provided with metal rotary disk, the upper surface of metal rotary disk is provided with METAL HEATING PROCESS box, and rosette electrode is placed on METAL HEATING PROCESS box upper surface; When carrying out sample to be tested charge injection, sample to be tested is positioned at multistylus electrode below; When carrying out surface potential decay measurement, sample to be tested is positioned at condenser type static probe below;
Described temperature control system comprises the first heater being arranged in METAL HEATING PROCESS box, and be arranged on the secondary heating mechanism on the insulating carriage of metal aluminum sheet below, temperature controller control linkage first heater and secondary heating mechanism outside constant temperature oven.
Described multistylus electrode adopts stainless pin, needle point radius-of-curvature 5 μ m; In multistylus electrode, outermost many pin electrodes are that regular hexagon distributes, and the mid point on each summit of regular hexagon and each limit is provided with pin electrode, and the length of outermost many pin electrodes is 9mm; In multistylus electrode, time outer field many pin electrodes are that regular hexagon distributes, and the mid point on each summit of regular hexagon and each limit is provided with pin electrode, and the length of inferior outer field many pin electrodes is 11mm; In multistylus electrode, many pin electrodes of inner side are that regular hexagon distributes, and each summit of regular hexagon and orthohexagonal center be provided with pin electrode, and the length of many pin electrodes of inner side is 12mm, and many pin electrodes of inner side are apart from sample to be tested upper surface 40mm; Many pin electrodes of outermost many pin electrodes, inferior outer field many pin electrodes and inner side form the regular hexagon that same center and the length of side are successively decreased.
Copper electrode diameter 120mm in described rosette electrode, thickness 10mm; Aluminium electrode diameter 250mm, thickness 10mm; The eccentric distance of copper electrode and aluminium electrode is 60mm, and copper electrode and aluminium electrode are bolted.
Described adjusting insulation fixed mount comprises insulation fixed mount and position adjusting mechanism, and condenser type static probe is fixed on position adjusting mechanism.
Aluminium electrode in described metal rotary disk, METAL HEATING PROCESS box and rosette electrode arranges from bottom to up and is bolted.
After described first heater and secondary heating mechanism parallel connection, by the temperature controller outside constant temperature oven, controlled, first heater comprises two thermopairs of series connection, and secondary heating mechanism adopts quartzy infrared heating pipe.
In described constant temperature oven, be also provided with humidity conditioner, humidity conditioner adopts solid drier.
Between described copper electrode and sample to be tested, be provided with conduction silicone grease.
The utlity model has following beneficial effect:
The utility model can be measured trap level and the trap density parameter of solid dielectric material, and can distinguish electron type and two kinds of traps of cavity type, easy to operate.Applicability is extensive, and the utility model had both been applicable to inorganic insulating material, as the test of the insulating material Trap Characteristics such as aluminium oxide, processable ceramic, is also applicable to the test of insulating material of polymer and oil-impregnated paper insulation Trap Characteristics simultaneously.
The utility model is designed with double heater, double heater heating in parallel, and carry out temperature controller regulation and control by external temperature controller; One of them heating arrangement is placed in in the METAL HEATING PROCESS box being fixedly connected with rosette electrode, realizes the direct preheating to sample to be tested; Another heating arrangement is fixed on the insulating carriage of metal aluminum sheet below, by heated with ambient air being realized to the control to environment temperature.The design of double heater can realize the direct preheating to sample to be tested, makes dielectric substance obtain more sufficient charge injection, guarantees that in constant temperature oven, Temperature Distribution is more even simultaneously, has improved the control accuracy of constant temperature the temperature inside the box.
Metal rotary disk is placed on a metal aluminum sheet supporting with insulating carriage, and the position angle that the design of metal rotary disk can realize sample to be tested regulates, and can realize at sample to be tested charge injection and surface potential decay and measure free quick switching under two states.
The utility model adopts multistylus electrode, the distance on the distributing position of each pin, the length of pin and needle point and sample to be tested surface can calculate by finite element method, make spininess electric field reach the state of being uniformly distributed, reach the effect to abundant, the even iunjected charge of specimen surface.
Accompanying drawing explanation
Fig. 1 is the structural representation of three electrode corona charging systems in the utility model;
Fig. 2 is the schematic diagram of surface potential limnograph system in the utility model;
Fig. 3 is the schematic diagram of metal rotary disk in the utility model;
Fig. 4 is rotary support system schematic in the utility model;
Fig. 5 is the distribution schematic diagram of multistylus electrode in the utility model.
Embodiment
As shown in Figures 1 to 5, solid dielectric material trap parameters acquisition system described in the utility model, comprises constant temperature oven 11 and is arranged on three electrode corona charging systems, surface potential measurement system, rotary support system and the temperature control system in constant temperature oven 11.Three electrode corona charging systems are for carrying out charge injection to sample to be tested 3, surface potential measurement system is for adopting cordless to carry out the test of surface potential decay to sample to be tested 3, rotary support system is used for realizing sample to be tested 3 to be switched fast under charge injection pattern and surface potential decay measurement, the transient potential information after having charged with Measurement accuracy; Temperature control system, for realizing the adjustment of experimental situation temperature, to obtain charge injection comparatively fully, guarantees experiment effect.
In the utility model, three electrode corona charging systems comprise the multistylus electrode 1 of coaxial setting from top to bottom and the rosette electrode 2 of ground connection, and multistylus electrode 1 connects DC charging power supply, and multistylus electrode 1 adopts stainless pin, needle point radius-of-curvature 5 μ m; In multistylus electrode 1, outermost many pin electrodes are that regular hexagon distributes, and the mid point on each summit of regular hexagon and each limit is provided with pin electrode, and the length of outermost many pin electrodes is 9mm; In multistylus electrode 1, time outer field many pin electrodes are that regular hexagon distributes, and the mid point on each summit of regular hexagon and each limit is provided with pin electrode, and the length of inferior outer field many pin electrodes is 11mm; In multistylus electrode 1, many pin electrodes of inner side are that regular hexagon distributes, and each summit of regular hexagon and orthohexagonal center are provided with pin electrode, the length of many pin electrodes of inner side is 12mm, and many pin electrodes of inner side are apart from sample to be tested 3 upper surface 40mm; Many pin electrodes of outermost many pin electrodes, inferior outer field many pin electrodes and inner side form the regular hexagon that same center and the length of side are successively decreased.Owing to adopting multistylus electrode 1, the distributing position of each pin in multistylus electrode 1, the distance of the length of pin and needle point and specimen surface can calculate by finite element method, make spininess electric field reach the state of being uniformly distributed, reach the effect to sample to be tested 3 abundant, the even iunjected charges in surface.
The upper surface of rosette electrode 2 is used for placing sample to be tested 3, and rosette electrode 2 comprises copper electrode and the aluminium electrode of contact up and down and eccentric setting.Copper electrode diameter 120mm in rosette electrode 2, thickness 10mm; Aluminium electrode diameter 250mm, thickness 10mm; The eccentric distance of copper electrode and aluminium electrode is 60mm, and copper electrode and aluminium electrode are bolted.The electrically contacting property of copper electrode surface fine polishing to guarantee that sample to be tested 3 and copper electrode are good, and be provided with conduction silicone grease between copper electrode and sample to be tested 3.
Described surface potential measurement system comprises the condenser type static probe 4 being arranged on adjusting insulation fixed mount 5, adjusting insulation fixed mount 5 comprises insulation fixed mount 5 and position adjusting mechanism 6, condenser type static probe 4 is fixed on position adjusting mechanism 6, and the distance of condenser type static probe 4 and sample to be tested 3 upper surfaces is by carrying out accurate adjustment by position adjusting mechanism 6.The output terminal of condenser type static probe 4 connects signal conditioning circuit 7 and the signal acquisition circuit 8 outside constant temperature oven 11 successively, signal acquisition circuit 8 is sent to computing machine by signal, by existing software, process, computing machine can carry out uninterrupted sampling and record automatically to sample to be tested 3 surface potential decays that record.
Described rotary support system comprises that the upper surface being arranged in constant temperature oven 11 is the insulating carriage 13 of metal aluminum sheet 12, and the upper surface of metal aluminum sheet 12 is provided with metal rotary disk 9.The upper surface of metal rotary disk 9 is provided with METAL HEATING PROCESS box 10, and METAL HEATING PROCESS box 10 is of a size of 250mm * 250mm * 20mm, and rosette electrode 2 is placed on METAL HEATING PROCESS box 10 upper surfaces.Aluminium electrode in metal rotary disk 9, METAL HEATING PROCESS box 10 and rosette electrode 2 arranges from bottom to up and is bolted.The position angle that metal rotary disk 9 can realize sample to be tested 3 regulates, and can realize at sample to be tested 3 and freely switching under charge injection and surface potential decay measurement two states.When carrying out sample to be tested 3 charge injection, sample to be tested 3 is positioned at multistylus electrode 1 below; When carrying out surface potential decay while measuring, can pass through rotating metallic rotating disk 9, make sample to be tested 3 be positioned at condenser type static 4 belows of popping one's head in.
Described temperature control system comprises the first heater 14 being arranged in METAL HEATING PROCESS box 10, and be arranged on the secondary heating mechanism 15 on metal aluminum sheet 12 below insulating carriages 13, temperature controller control linkage first heater 14 and secondary heating mechanism 15 outside constant temperature oven 11.After first heater 14 and secondary heating mechanism 15 parallel connections, by the temperature controller outside constant temperature oven 11, controlled, guarantee that temperature control precision is ± 0.1 ℃.First heater 14 comprises two thermopairs of series connection, and secondary heating mechanism 15 adopts quartzy infrared heating pipe.
In constant temperature oven 11, be also provided with humidity conditioner, humidity conditioner adopts solid drier.In the present embodiment, solid drier can adopt transformer drying agent silica gel, guarantees that humidity is controlled at below 40%, to meet requirement of experiment.
The utility model is being used, first with conduction silicone grease, sample to be tested 3 is attached to the copper electrode upper surface in rosette electrode 2, multistylus electrode 1 remains 40mm with sample to be tested 3 distances, then by apply+10kV of multistylus electrode 1 or-charging voltage of 10kV, each iunjected charge time is 10~30min.During charging, utilize temperature control system to heat rosette electrode 2, make it remain on 70 ℃, to guarantee abundant iunjected charge.Applying under High Pressure, corona discharge occurs at the needle point place of multistylus electrode 1, thereby air is ionized and produces a large amount of charging points, the needle point of multistylus electrode 1 forms ionized region around.Take and apply reverse voltage as example, under electric field action, negative ion is to sample to be tested 3 surface drifts, because the Electric Field Distribution between multistylus electrode 1 and the rosette electrode 2 below multistylus electrode 1 is more even, negative ion can form uniform charge shift district between multistylus electrode 1 and sample to be tested 3, electronics in negative ion will be captured by the trap states on sample to be tested 3 surfaces, thereby obtains uniform surface charging effect.
In experimentation, after sample charge injection, remove DC charging voltage, at sample to be tested 3 surface coverage aluminium foil short circuit dischanges, keep short circuit approximately 1~5s to remove the free charge (non-trapped charge) of sample to be tested 3 surface depositions.After short circuit dischange, by rotating metallic rotating disk 9, drive rosette electrode 2 that sample to be tested 3 surface charging regions are moved to condenser type static probe 4 times, adopt the surface potential decay of non-contact mode measuring sample to be tested 3, keeping condenser type static probe 4 and the distance on sample to be tested 3 surfaces is 2mm.The signal of condenser type static probe 4 outputs in the signal acquisition circuit 8 that access is connected with computing machine, can carry out continuous sampling to the surface potential of sample to be tested 3 by computing machine after being nursed one's health by signal conditioning circuit 7.In experiment, generally signal acquisition circuit 8 is set as to every 1s once sampling.Because the attenuation characteristic of surface potential is affected by environment greatly, therefore whole experiment must be carried out in constant temperature oven 11, keeps temperature strictly constant in experimentation, and controls constant temperature oven 11 internal relative humidities lower than 40% by placing solid drier.According to Isothermal Current attenuation theory, in surface potential Isothermal Decay process, the electric charge in shallow trap in medium first discharges, and discharges after electric charge in deep trap.Hot release current time to time change under steady temperature, the variation of this electric current has reflected the regularity of distribution of trap level.
By specimen surface potential decay characteristic under isothermy, can calculate Isothermal Decay electric current, and and then calculate trap level and the trap density parameter of sample.
The utility model can be measured trap level and the trap density parameter of solid dielectric material, and can distinguish electron type and two kinds of traps of cavity type, easy to operate.The utility model had both been applicable to inorganic insulating material, as the test of the insulating material Trap Characteristics such as aluminium oxide, processable ceramic, was also applicable to the test of insulating material of polymer and oil-impregnated paper insulation Trap Characteristics simultaneously.The utility model provides theory and technology support for studying the Trap Characteristics of solid dielectric material, can be the aging rule research of trap parameters characterize polymers insulating material aging performance and polymkeric substance, and Solid Dielectric Surface electrification phenomenon and provide a kind of effective analysis means to the research of the aspects such as edge flashing performance impact.
Claims (8)
1. a solid dielectric material trap parameters acquisition system, is characterized in that: comprise constant temperature oven and be arranged on three electrode corona charging systems, surface potential measurement system, rotary support system and the temperature control system in constant temperature oven;
Three described electrode corona charging systems comprise the multistylus electrode of coaxial setting from top to bottom and the rosette electrode of ground connection, multistylus electrode connects DC charging power supply, the upper surface of rosette electrode is used for placing sample to be tested, and rosette electrode comprises copper electrode and the aluminium electrode of contact up and down and eccentric setting;
Described surface potential measurement system comprises the condenser type static probe being arranged on adjusting insulation fixed mount, and the output terminal of condenser type static probe connects signal conditioning circuit and the signal acquisition circuit outside constant temperature oven successively;
Described rotary support system comprises the insulating carriage that the upper surface that is arranged in constant temperature oven is metal aluminum sheet, the upper surface of metal aluminum sheet is provided with metal rotary disk, the upper surface of metal rotary disk is provided with METAL HEATING PROCESS box, and rosette electrode is placed on METAL HEATING PROCESS box upper surface; When carrying out sample to be tested charge injection, sample to be tested is positioned at multistylus electrode below; When carrying out surface potential decay measurement, sample to be tested is positioned at condenser type static probe below;
Described temperature control system comprises the first heater being arranged in METAL HEATING PROCESS box, and be arranged on the secondary heating mechanism on the insulating carriage of metal aluminum sheet below, temperature controller control linkage first heater and secondary heating mechanism outside constant temperature oven.
2. solid dielectric material trap parameters acquisition system according to claim 1, is characterized in that: described multistylus electrode adopts stainless pin, needle point radius-of-curvature 5 μ m; In multistylus electrode, outermost many pin electrodes are that regular hexagon distributes, and the mid point on each summit of regular hexagon and each limit is provided with pin electrode, and the length of outermost many pin electrodes is 9mm; In multistylus electrode, time outer field many pin electrodes are that regular hexagon distributes, and the mid point on each summit of regular hexagon and each limit is provided with pin electrode, and the length of inferior outer field many pin electrodes is 11mm; In multistylus electrode, many pin electrodes of inner side are that regular hexagon distributes, and each summit of regular hexagon and orthohexagonal center be provided with pin electrode, and the length of many pin electrodes of inner side is 12mm, and many pin electrodes of inner side are apart from sample to be tested upper surface 40mm; Many pin electrodes of outermost many pin electrodes, inferior outer field many pin electrodes and inner side form the regular hexagon that same center and the length of side are successively decreased.
3. solid dielectric material trap parameters acquisition system according to claim 2, is characterized in that: copper electrode diameter 120mm in described rosette electrode, thickness 10mm; Aluminium electrode diameter 250mm, thickness 10mm; The eccentric distance of copper electrode and aluminium electrode is 60mm, and copper electrode and aluminium electrode are bolted.
4. solid dielectric material trap parameters acquisition system according to claim 3, is characterized in that: described adjusting insulation fixed mount comprises insulation fixed mount and position adjusting mechanism, and condenser type static probe is fixed on position adjusting mechanism.
5. solid dielectric material trap parameters acquisition system according to claim 4, is characterized in that: the aluminium electrode in described metal rotary disk, METAL HEATING PROCESS box and rosette electrode arranges from bottom to up and is bolted.
6. solid dielectric material trap parameters acquisition system according to claim 5, it is characterized in that: after described first heater and secondary heating mechanism parallel connection, by the temperature controller outside constant temperature oven, controlled, first heater comprises two thermopairs of series connection, and secondary heating mechanism adopts quartzy infrared heating pipe.
7. solid dielectric material trap parameters acquisition system according to claim 6, is characterized in that: in described constant temperature oven, be also provided with humidity conditioner, humidity conditioner adopts solid drier.
8. solid dielectric material trap parameters acquisition system according to claim 7, is characterized in that: between described copper electrode and sample to be tested, be provided with conduction silicone grease.
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