CN204440211U - Closed compact impulse voltage generator waveform adjustment device - Google Patents
Closed compact impulse voltage generator waveform adjustment device Download PDFInfo
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- CN204440211U CN204440211U CN201520134305.1U CN201520134305U CN204440211U CN 204440211 U CN204440211 U CN 204440211U CN 201520134305 U CN201520134305 U CN 201520134305U CN 204440211 U CN204440211 U CN 204440211U
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- 238000009413 insulation Methods 0.000 claims abstract description 76
- 239000012212 insulator Substances 0.000 claims abstract description 71
- 230000011218 segmentation Effects 0.000 claims abstract description 38
- 239000011148 porous material Substances 0.000 claims abstract description 7
- 238000000605 extraction Methods 0.000 claims abstract description 4
- 238000012360 testing method Methods 0.000 claims description 34
- 229910018503 SF6 Inorganic materials 0.000 claims description 17
- SFZCNBIFKDRMGX-UHFFFAOYSA-N sulfur hexafluoride Chemical compound FS(F)(F)(F)(F)F SFZCNBIFKDRMGX-UHFFFAOYSA-N 0.000 claims description 17
- 238000003032 molecular docking Methods 0.000 claims description 15
- 229960000909 sulfur hexafluoride Drugs 0.000 claims description 14
- 238000007789 sealing Methods 0.000 claims description 6
- 239000003990 capacitor Substances 0.000 claims description 4
- 238000013016 damping Methods 0.000 claims description 4
- 238000009863 impact test Methods 0.000 abstract description 3
- 238000000034 method Methods 0.000 description 11
- 238000013461 design Methods 0.000 description 6
- 230000013011 mating Effects 0.000 description 6
- 238000009434 installation Methods 0.000 description 5
- 238000010276 construction Methods 0.000 description 4
- 230000008859 change Effects 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 238000010923 batch production Methods 0.000 description 1
- 230000008901 benefit Effects 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 230000005684 electric field Effects 0.000 description 1
- 238000002474 experimental method Methods 0.000 description 1
- 230000003116 impacting effect Effects 0.000 description 1
- 230000008676 import Effects 0.000 description 1
- 238000012423 maintenance Methods 0.000 description 1
- 231100000252 nontoxic Toxicity 0.000 description 1
- 230000003000 nontoxic effect Effects 0.000 description 1
- 230000002265 prevention Effects 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 238000012545 processing Methods 0.000 description 1
- 230000001105 regulatory effect Effects 0.000 description 1
- 230000035939 shock Effects 0.000 description 1
- 238000007711 solidification Methods 0.000 description 1
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Abstract
The utility model relates to closed compact impulse voltage generator waveform adjustment device, its sealed insulation shell offers air-filled pore, full skirt insulator top, top is connected the top of sealed insulation shell, full skirt insulator bottom, bottom is connected the bottom of sealed insulation shell, insulating carriage between resistance is fixedly connected with between top full skirt insulator and bottom full skirt insulator, segmentation is noninductive, and wavefront resistance is fixed on the top of insulating carriage between resistance, and half peak resistance is fixed on insulating carriage bottom between resistance; Segmentation is noninductive one end of wavefront resistance with one end of half peak resistance by being connected rear extraction, segmentation is noninductive wavefront resistance is provided with three leading-out terminals successively, three leading-out terminals connect different gears corresponding in driving switch respectively by wire, the outlet shelves of driving switch connect rear extraction by wire, and the other end of half peak resistance connects the earth point of sealed insulation shell.The utility model solves the problem that current compact impact test apparatus waveform cannot regulate.
Description
Technical field
The utility model relates to and super, extra-high voltage electric transmission and transformation equipment impulse test field, is specifically related to a kind of closed compact impulse voltage generator waveform adjustment device.
Background technology
Lightning impulse voltage test is the important Insulation Test project of converting equipment, can discovering device Insulation Problems timely and effectively, is the effective means of prevention power equipment generation major accident.At present, the important power equipments such as the high-power transformer of super, extra-high voltage gas-insulated switchgear (Gas Insulated Switchgear-GIS), batch production maintenance all need to carry out lightning impulse test at the scene, and conventional impact voltage generator all adopts open type pyramidal structure, bulky, split transportation cost is higher, as CDYH-4800 surge generator overall height 17.2m, floor area 6.07 × 6.6m, heavily about 30t, and field erected workload is large, cannot move, cause the on-the-spot insulation characterisitic test of large scale electrical power unit to carry out.Compact closed gas insulation surge voltage generating means adopts high insulating gas as major insulation medium, significantly reduces the volume and weight of test unit, efficiently solves the problems such as test unit transport and in-site installation.
But, electrical equipment that is super, extra-high voltage grade is considered because closed compact impulse voltage generator design is main, inner wave regulating resistor solidification, and this device adopts compact enclosed construction, (space of closed compact impulse voltage generator is less as conventional impact, cannot to carry out waveform adjustment by the artificial mode changing resistance, and be enclosed construction, people cannot enter, resistance adjustment difficulty), also do not design suitable waveform adjustment device for above-mentioned new closed compact impulse voltage generator at present.
Utility model content
The purpose of this utility model is to provide a kind of closed compact impulse voltage generator waveform adjustment device, this device adopts high insulating property gas as major insulation medium, reduce the requirement along face creepage distance to inner waveform adjustment resistance and other components and parts itself, shorten the insulation distance between each components and parts; Meanwhile, test unit adopts segmentation no-induction wavefront resistance and driving switch, realizes effective adjustment of resistance, solves the problem that current compact impact test apparatus waveform cannot regulate.
For solving the problems of the technologies described above, a kind of closed compact impulse voltage generator waveform adjustment device disclosed in the utility model, it is characterized in that: it comprises sealed insulation shell, be arranged on the driving switch on sealed insulation shell, be arranged on the impulse voltage generator docking port of sealed insulation shell one end, be arranged on the tested electrical equipment docking port of the sealed insulation shell other end, be arranged on the first full skirt insulator of sealed insulation enclosure, second full skirt insulator, 3rd full skirt insulator, 4th full skirt insulator, 5th full skirt insulator, segmentation is noninductive wavefront resistance and half peak resistance, wherein, described sealed insulation shell offers air-filled pore, described first full skirt insulator, second full skirt insulator, the top of the top fixed connection and sealing insulation crust of the 3rd full skirt insulator, the bottom of the bottom fixed connection and sealing insulation crust of described 4th full skirt insulator and the 5th full skirt insulator, insulating carriage between the first resistance is fixedly connected with between described first full skirt insulator and the 4th full skirt insulator, insulating carriage between the second resistance is fixedly connected with between second full skirt insulator and the 5th full skirt insulator, described segmentation is noninductive, and wavefront resistance is fixed on the top of insulating carriage between insulating carriage and the second resistance between the first resistance, half peak resistance is fixed on the bottom of insulating carriage between insulating carriage and the second resistance between the first resistance,
Described segmentation is noninductive is drawn by impulse voltage generator docking port after one end of wavefront resistance is connected by wire with one end of half peak resistance, segmentation is noninductive wavefront resistance is provided with the first leading-out terminal successively, second leading-out terminal and the 3rd leading-out terminal, described 3rd leading-out terminal is positioned at the other end of the noninductive wavefront resistance of segmentation, described first leading-out terminal, second leading-out terminal is connected different gears corresponding in driving switch with the 3rd leading-out terminal respectively by wire, the outlet shelves of described driving switch are connected rear by tested electrical equipment docking port extraction by wire, the other end of described half peak resistance connects the earth point of sealed insulation shell.
The utility model adopts high insulating property gas (sulfur hexafluoride) as major insulation medium, reduce the requirement along face creepage distance to inner waveform adjustment resistance and other components and parts itself, shorten the insulation distance (achieving miniaturization) between each components and parts; Meanwhile, test unit adopts segmentation no-induction wavefront resistance and driving switch to match, and achieves effective adjustment of resistance, meets the requirement of new-type compact impact test apparatus waveform adjustment, ensure that the efficiency of waveform adjustment.
The utility model expands the scope of application of compact impulse voltage generator by segmentation wavefront resistance and many driving switch, simplify the waveform adjustment process of impulse test, therefore, can significantly reduce impulse test workload, for the popularization of the closed impulse voltage generator of compact provides powerful guarantee; Simultaneously, the good sulfur hexafluoride gas of the utility model insulating property is as major insulation medium, significantly shorten the insulation distance between each device size and device, thus (compact impulse voltage generator and its waveform adjustment device compare traditional CDYH-4800 type surge generator to reduce the volume and weight impacting generating means, its volume and weight is all less), be conducive to the installation and handling etc. of test unit, improve the work efficiency of site test, reduce the requirement of experiment hall to installation space.
Accompanying drawing explanation
Fig. 1 be compact impulse voltage generator with the utility model waveform adjustment device dock schematic diagram;
Fig. 2 is structural representation of the present utility model;
Fig. 3 is cross section structure schematic diagram of the present utility model;
Fig. 4 is the schematic cross-section of driving switch in the utility model;
Fig. 5 is circuit catenation principle figure of the present utility model.
Wherein, 1-compact impulse voltage generator, 2-closed compact impulse voltage generator waveform adjustment device, 3-sealed insulation shell, 4-driving switch, 4.1-circular switch insulation support, 4.2-the first gear, 4.3-the second gear, 4.4-third gear, 4.5-outlet shelves, 4.6-switch rotating disk, 4.7-insulation rotary axis, 4.8-conduction plectrum, 5-impulse voltage generator docking port, 6-tested electrical equipment docking port, 7-the first full skirt insulator, 8-the second full skirt insulator, 9-the three full skirt insulator, 10-the four full skirt insulator, 11-the five full skirt insulator, 12-segmentation is noninductive wavefront resistance, 13-half peak resistance, insulating carriage between the 14-the first resistance, insulating carriage between the 15-the second resistance, 16-the first leading-out terminal, 17-the second leading-out terminal, 18-the three leading-out terminal, 19-air-filled pore, 20-earth point, 21-the first shading ring, 22-secondary shielding ring, 23-insulating frame, 24-gear supporting insulator, 25-arc conductive connecting device.
Embodiment
Below in conjunction with the drawings and specific embodiments, the utility model is described in further detail:
Closed compact impulse voltage generator waveform adjustment device 2 of the present utility model, as shown in Fig. 1 ~ 5, it comprises sealed insulation shell 3, be arranged on the driving switch 4 on sealed insulation shell 3, be arranged on the impulse voltage generator docking port 5 (for connecting compact impulse voltage generator 1) of sealed insulation shell 3 one end, be arranged on the tested electrical equipment docking port 6 of sealed insulation shell 3 other end, be arranged on the first full skirt insulator 7 of sealed insulation shell 3 inside, second full skirt insulator 8, 3rd full skirt insulator 9, 4th full skirt insulator 10, 5th full skirt insulator 11, segmentation is noninductive wavefront resistance 12 and half peak resistance 13 (the first full skirt insulator 7, second full skirt insulator 8 is equal with the 3rd full skirt insulator 9 length, 4th full skirt insulator 10, the length of the 5th full skirt insulator 11 is equal, first full skirt insulator 7 length is greater than the 4th full skirt insulator 10), wherein, described sealed insulation shell 3 offers air-filled pore 19 (for sulfur hexafluoride gas of coming in and going out), described first full skirt insulator 7, second full skirt insulator 8, the top of the top fixed connection and sealing insulation crust 3 of the 3rd full skirt insulator 9, the bottom of the bottom fixed connection and sealing insulation crust 3 of described 4th full skirt insulator 10 and the 5th full skirt insulator 11, insulating carriage 14 between the first resistance is fixedly connected with between described first full skirt insulator 7 and the 4th full skirt insulator 10, insulating carriage 15 between the second resistance is fixedly connected with between second full skirt insulator 8 and the 5th full skirt insulator 11, described segmentation is noninductive, and wavefront resistance 12 is fixed on the top of insulating carriage 15 between insulating carriage 14 and the second resistance between the first resistance, half peak resistance 13 is fixed on the bottom of insulating carriage 15 between insulating carriage 14 and the second resistance between the first resistance,
Drawn by impulse voltage generator docking port 5 after one end of described segmentation is noninductive wavefront resistance 12 is connected by wire with one end of half peak resistance 13, segmentation is noninductive wavefront resistance 12 is provided with the first leading-out terminal 16 successively, second leading-out terminal 17 and the 3rd leading-out terminal 18, described 3rd leading-out terminal 18 is positioned at the other end of the noninductive wavefront resistance 12 of segmentation, described first leading-out terminal 16, second leading-out terminal 17 is connected different gears corresponding in driving switch 4 with the 3rd leading-out terminal 18 respectively by wire, drawn by tested electrical equipment docking port 6 after the outlet shelves 4.5 of described driving switch 4 are connected by wire, the other end of described half peak resistance 13 connects the earth point 20 of sealed insulation shell 3.
In technique scheme, described segmentation is noninductive one end of wavefront resistance 12 and one end of half peak resistance 13 are provided with the first shading ring 21, and the first leading-out terminal 16, second leading-out terminal 17 and the 3rd leading-out terminal 18 of described segmentation is noninductive wavefront resistance 12 are all provided with secondary shielding ring 22.
In technique scheme, one end that one end of described segmentation is noninductive wavefront resistance 12 is fixedly connected with the first shading ring 21, half peak resistance 13 by insulating frame 23 is fixedly connected with the first shading ring 21 by insulating frame 23; Described first leading-out terminal 16, second leading-out terminal 17 and the 3rd leading-out terminal 18 are all fixedly connected with secondary shielding ring 22 by corresponding insulating frame 23.Described segmentation is noninductive wavefront resistance 12 and half peak resistance 13 are cylindrical structural, and each lead end all have employed shielding processing.Because the electric connecting member of resistance end may exist wedge angle and burr, therefore adopt shading ring, electric fields uniform is distributed.
In technique scheme, by two sections of resistance, (wavefront resistance 12 and half peak resistance 13, the hi-line all introduced with impulse voltage generator docking port 5 is connected described half peak resistance 13, therefore identical at the voltage of end.But the direct ground connection of afterbody of half peak resistance 13, namely tail voltage is 0, and the afterbody of wavefront resistance 12 connects test product, and tail voltage is higher.Therefore, along with resistance is from end to afterbody, voltage difference between wavefront resistance 12 and half peak resistance 13 becomes large, for expanding the insulation distance between two resistance, half peak resistance 13 adopts segmentation structure) connect and compose, connected by arc conductive connecting device 25 between two sections of resistance, the end face of first paragraph resistance and sealed insulation shell 3, all gap is had between bottom surface and side, second segment resistance connects the earth point 20 of sealed insulation shell 3 bottom surface, and second segment resistance is perpendicular to sealed insulation shell 3 bottom surface, the length of above-mentioned 4th full skirt insulator 10 and the 5th full skirt insulator 11 is less than the length of the first full skirt insulator 7, half peak resistance 13 is arranged the 4th relatively little full skirt insulator 10 and the 5th full skirt insulator 11, mainly consideration is applied to super, its surge voltage of the surge generator of extra-high voltage electric power equipment is larger, the pressure drop of half peak resistance 8 is larger, adopt little umbrella skirt construction to increase creepage distance, when voltage drop is to certain level, the relative voltage of segmentation is noninductive wavefront resistance 12 and half peak resistance 13 increases, now for guaranteeing the insulation distance between two resistance, the latter half of half peak resistance 13 adopts vertical layout (to be convenient to install, and insulation distance increase between this arrangement half peak resistance 13 afterbody and wavefront resistance 12 afterbody is the fastest).The known test product for different capabilities (transformer, reactor, GIS, lightning arrester, sleeve pipe etc.) as calculated, the change of half peak value is very little, and half therefore single peak value resistance value can meet test demand;
In technique scheme, described driving switch 4, as shown in Figure 4 (in Fig. 4 dotted line be motion in conduction plectrum 4.8 and insulation rotary axis 4.7), comprise circular switch insulation support 4.1, branch is arranged in the first gear 4.2 on circular switch insulation support 4.1 by respective notch supporting insulator 24, second gear 4.3, third gear 4.4 and outlet shelves 4.5, be positioned at the switch rotating disk 4.6 of sealed insulation shell 3 outside, the insulation rotary axis 4.7 that one end is fixedly connected with switch rotating disk 4.6, the conduction plectrum 4.8 be fixedly connected with insulation rotary axis 4.7 other end, described conduction plectrum 4.8 connects outlet shelves 4.5 by wire, conduction plectrum 4.8 can under the drive of insulation rotary axis 4.7 respectively with the first gear 4.2, second gear 4.3 contacts with third gear 4.4, described first gear 4.2 connects the first leading-out terminal 16 by wire, second gear 4.3 connects the second leading-out terminal 17 by wire, third gear 4.4 connects the 3rd leading-out terminal 18 by wire.
In technique scheme, the resistance value (itself pressure drop is less, can not consider the edge flashing of itself) of described segmentation is noninductive wavefront resistance 12 is determined by following formula:
T
f≈2.33(R
d+R
f)C
1C
2/(C
1+C
2)
Wherein T
ffor wave front time, R
dfor the total damping resistance of surge generator inside, R
ffor the noninductive wavefront resistance of segmentation, C
1for the capacitor of impulse voltage generator, C
2for test product total capacitance.
In technique scheme, the resistance value of described half peak resistance 13 is determined by following formula:
T
t≈0.693(R
d+R
t)(C
1+C
2),
Wherein T
tbe half time to peak, R
tbe half peak value resistance, R
dfor the total damping resistance of surge generator inside, C
1for the capacitor of impulse voltage generator, C
2for test product total capacitance.
In technique scheme, described gear supporting insulator 24 opposing circular switch insulation support 4.1 is for being in tilted layout.Above-mentioned driving switch 4 is for realizing resistance adjustment, and play electrical connection effect, therefore its connector may withstand shocks the maximum output voltage of voltage generator, insulating requirements is met along face creepage distance for what guarantee each gear supporting insulator 24, this gear supporting insulator 24 adopts and is in tilted layout, and in the compact surge generator that electric pressure is higher, this place's insulator can adopt band umbrella skirt construction.The leading-out terminal of each gear of driving switch 4 and the noninductive wavefront resistance 12 of segmentation is electrically connected by connecting line, owing to certainly existing certain voltage difference between connecting line each when different gear, the insulation distance between the insulating structure design of this connecting line and connecting line can according to the experimental formula E of lightning impulse design voltage
dt=75 (10p)
0.75kV/cm determines, wherein p is air pressure (Mpa).Thus show that air pressure be the sulfur hexafluoride gas of 0.4MPa is 212.1kV at the lightning impulse voltage of 1cm.
In technique scheme, described sealed insulation shell 3 is sulfur hexafluoride gas by the gas that air-filled pore 19 is filled with, in described sealed insulation shell 3, the air pressure range of sulfur hexafluoride gas is that (this air pressure is that air pressure commonly used by sulfur hexafluoride gas electrical equipment to 0.3 ~ 0.5MPa, design experiences is very ripe, and the insulation characterisitic of sulfur hexafluoride gas is about linear relationship within the scope of this, raises nonlinear characteristic with air pressure and strengthen.If air pressure reduces, then sulfur hexafluoride gas-insulating intensity is less, has little significance, if air pressure is higher, improve more, but sulfur hexafluoride gas-insulating intensity rises less to the requirement of device housings intensity).Sulfur hexafluoride gas has good insulation preformance, the advantage such as nontoxic, lightweight.
In technique scheme, described segmentation is noninductive wavefront resistance 12 and half peak resistance 13 are noninductive resistance.Avoid the increase of impulse voltage generator loop inductance.
Technique scheme designs for the closed impulse voltage generator of 3000kV/300kJ compact, the capacity that is applicable to of impulse voltage generator can be made to be the power equipment of 300pF ~ 15000pF, meet the test demand of current most domestic high voltage electric power equip ment, the leading-out terminal when test product volume change is larger by increasing driving switch 4 gear and the noninductive wavefront resistance 12 of segmentation realizes;
The course of work of the present utility model is:
Step 1: test product (as: GIS etc.) is positioned at installing zone, the closed impulse voltage generator of compact and closed waveform adjustment device 2 are arranged on hovercar, and now surge generator 1 and waveform adjustment device inside are all filled with the SF6 gas requiring pressure.
Step 2: the position of adjustment hovercar, is made the mating interface 6 of waveform adjustment device 2 corresponding with the mating interface of test product, completed the installation of mating interface 6 after removing the cover plate of each interface by bolt and O-ring seal;
Step 3: inflate retracting device (this inflation retracting device can for meeting the inflation retracting device of DL/T 662-2009 " sulfur hexafluoride gas-filled and retracting device " standard) by SF6 and be filled with SF6 gas to mating interface 6.
Step 4: according to the model of test product or the delivery test record of test product, tentatively determine the wavefront resistance value needed for lightning impulse test, the driving switch 4 of adjustment waveform adjustment device 2, makes resistance value that wavefront resistance 12 imports in claimed range.
Step 5: the output voltage arranging impulse voltage generator 1 is the trial voltage of 50%, and charging starts test, by the coupling part of the conducting rod in impulse voltage generator 1, mating interface 5, wavefront resistance 12, driving switch 4, mating interface 6, high voltage is caused test product during test;
Step 6: check whether test waveform meets the demands (1.2 ± 30% μ s, 50 ± 20% μ s), if do not meet the demands, then readjusts the resistance value of wavefront resistance 12 according to waveform situation, again carries out 50% impulse voltage test;
Step 7: if waveform meets the demands, then the output voltage arranging impulse voltage generator is 100% trial voltage, completes impulse voltage test.
The content that this instructions is not described in detail belongs to the known prior art of professional and technical personnel in the field.
Claims (10)
1. a closed compact impulse voltage generator waveform adjustment device, it is characterized in that: it comprises sealed insulation shell (3), be arranged on the driving switch (4) on sealed insulation shell (3), be arranged on the impulse voltage generator docking port (5) of sealed insulation shell (3) one end, be arranged on the tested electrical equipment docking port (6) of sealed insulation shell (3) other end, be arranged on the first full skirt insulator (7) that sealed insulation shell (3) is inner, second full skirt insulator (8), 3rd full skirt insulator (9), 4th full skirt insulator (10), 5th full skirt insulator (11), segmentation is noninductive wavefront resistance (12) and half peak resistance (13), wherein, described sealed insulation shell (3) offers air-filled pore (19), described first full skirt insulator (7), second full skirt insulator (8), the top of the top fixed connection and sealing insulation crust (3) of the 3rd full skirt insulator (9), the bottom of the bottom fixed connection and sealing insulation crust (3) of described 4th full skirt insulator (10) and the 5th full skirt insulator (11), insulating carriage (14) between the first resistance is fixedly connected with between described first full skirt insulator (7) and the 4th full skirt insulator (10), insulating carriage (15) between the second resistance is fixedly connected with between second full skirt insulator (8) and the 5th full skirt insulator (11), described segmentation is noninductive, and wavefront resistance (12) is fixed on the top of insulating carriage (15) between insulating carriage (14) and the second resistance between the first resistance, half peak resistance (13) is fixed on the bottom of insulating carriage (15) between insulating carriage (14) and the second resistance between the first resistance,
Drawn by impulse voltage generator docking port (5) after described segmentation is noninductive one end of wavefront resistance (12) is connected by wire with one end of half peak resistance (13), segmentation is noninductive wavefront resistance (12) is provided with the first leading-out terminal (16) successively, second leading-out terminal (17) and the 3rd leading-out terminal (18), described 3rd leading-out terminal (18) is positioned at the other end of the noninductive wavefront resistance (12) of segmentation, described first leading-out terminal (16), second leading-out terminal (17) is connected different gears corresponding in driving switch (4) with the 3rd leading-out terminal (18) respectively by wire, the outlet shelves (4.5) of described driving switch (4) are connected rear by tested electrical equipment docking port (6) extraction by wire, the other end of described half peak resistance (13) connects the earth point (20) of sealed insulation shell (3).
2. closed compact impulse voltage generator waveform adjustment device according to claim 1, it is characterized in that: described segmentation is noninductive one end of wavefront resistance (12) and one end of half peak resistance (13) are provided with the first shading ring (21), first leading-out terminal (16) of described segmentation is noninductive wavefront resistance (12), the second leading-out terminal (17) and the 3rd leading-out terminal (18) are all provided with secondary shielding ring (22).
3. closed compact impulse voltage generator waveform adjustment device according to claim 2, it is characterized in that: one end of described segmentation is noninductive wavefront resistance (12) is fixedly connected with the first shading ring (21) by insulating frame (23), one end of half peak resistance (13) is fixedly connected with the first shading ring (21) by insulating frame (23); Described first leading-out terminal (16), the second leading-out terminal (17) and the 3rd leading-out terminal (18) are all fixedly connected with secondary shielding ring (22) by corresponding insulating frame (23).
4. closed compact impulse voltage generator waveform adjustment device according to claim 1, it is characterized in that: described half peak resistance (13) is connected and composed by two sections of resistance, connected by arc conductive connecting device (25) between two sections of resistance, the end face of first paragraph resistance and sealed insulation shell (3), between bottom surface and side, all there is gap, second segment resistance connects the earth point (20) of sealed insulation shell (3) bottom surface, and second segment resistance is perpendicular to sealed insulation shell (3) bottom surface.
5. closed compact impulse voltage generator waveform adjustment device according to claim 1, it is characterized in that: described driving switch (4) comprises circular switch insulation support (4.1), branch is arranged in the first gear (4.2) on circular switch insulation support (4.1) by respective notch supporting insulator (24), second gear (4.3), third gear (4.4) and outlet shelves (4.5), be positioned at the switch rotating disk (4.6) that sealed insulation shell (3) is outside, the insulation rotary axis (4.7) that one end is fixedly connected with switch rotating disk (4.6), the conduction plectrum (4.8) be fixedly connected with insulation rotary axis (4.7) other end, described conduction plectrum (4.8) connects outlet shelves (4.5) by wire, conduction plectrum (4.8) can under the drive of insulation rotary axis (4.7) respectively with the first gear (4.2), second gear (4.3) contacts with third gear (4.4), described first gear (4.2) connects the first leading-out terminal (16) by wire, second gear (4.3) connects the second leading-out terminal (17) by wire, third gear (4.4) connects the 3rd leading-out terminal (18) by wire.
6. closed compact impulse voltage generator waveform adjustment device according to claim 1, is characterized in that: the resistance value of described segmentation is noninductive wavefront resistance (12) is determined by following formula:
T
f≈2.33(R
d+R
f)c
1c
2/(c
1+c
2)
Wherein T
ffor wave front time, R
dfor the total damping resistance of surge generator inside, R
ffor the noninductive wavefront resistance of segmentation, c
1for the capacitor of impulse voltage generator, c
2for test product total capacitance.
7. closed compact impulse voltage generator waveform adjustment device according to claim 1, is characterized in that: the resistance value of described half peak resistance (13) is determined by following formula:
T
t≈0.693(R
d+R
t)(c
1+c
2),
Wherein T
tbe half time to peak, R
tbe half peak value resistance, R
dfor the total damping resistance of surge generator inside, c
1for the capacitor of impulse voltage generator, c
2for test product total capacitance.
8. closed compact impulse voltage generator waveform adjustment device according to claim 5, is characterized in that: described gear supporting insulator (24) opposing circular switch insulation support (4.1) is for being in tilted layout.
9. closed compact impulse voltage generator waveform adjustment device according to claim 5, it is characterized in that: described sealed insulation shell (3) is sulfur hexafluoride gas by the gas that air-filled pore (19) is filled with, the air pressure range of the interior sulfur hexafluoride gas of described sealed insulation shell (3) is 0.3 ~ 0.5MPa.
10. closed compact impulse voltage generator waveform adjustment device according to claim 1, is characterized in that: described segmentation is noninductive wavefront resistance (12) and half peak resistance (13) are noninductive resistance.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520134305.1U CN204440211U (en) | 2015-03-09 | 2015-03-09 | Closed compact impulse voltage generator waveform adjustment device |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520134305.1U CN204440211U (en) | 2015-03-09 | 2015-03-09 | Closed compact impulse voltage generator waveform adjustment device |
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| Publication Number | Publication Date |
|---|---|
| CN204440211U true CN204440211U (en) | 2015-07-01 |
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ID=53608052
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|---|---|---|---|
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104699150A (en) * | 2015-03-09 | 2015-06-10 | 国家电网公司 | Waveform regulating device of enclosed compact impulse voltage generator |
| CN105372463A (en) * | 2015-11-25 | 2016-03-02 | 国家电网公司 | Capacitive graded compact impulse voltage generator |
| CN105588959A (en) * | 2016-03-04 | 2016-05-18 | 云南电网有限责任公司电力科学研究院 | Mobile impulse current generator and method of use |
-
2015
- 2015-03-09 CN CN201520134305.1U patent/CN204440211U/en not_active Withdrawn - After Issue
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104699150A (en) * | 2015-03-09 | 2015-06-10 | 国家电网公司 | Waveform regulating device of enclosed compact impulse voltage generator |
| CN104699150B (en) * | 2015-03-09 | 2016-03-02 | 国家电网公司 | Closed compact impulse voltage generator waveform adjustment device |
| CN105372463A (en) * | 2015-11-25 | 2016-03-02 | 国家电网公司 | Capacitive graded compact impulse voltage generator |
| CN105372463B (en) * | 2015-11-25 | 2017-11-24 | 国家电网公司 | Capacitance grading formula compact impulse voltage generator |
| CN105588959A (en) * | 2016-03-04 | 2016-05-18 | 云南电网有限责任公司电力科学研究院 | Mobile impulse current generator and method of use |
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