CN2791657Y - Electric load general simulation device - Google Patents
Electric load general simulation device Download PDFInfo
- Publication number
- CN2791657Y CN2791657Y CN 200420097384 CN200420097384U CN2791657Y CN 2791657 Y CN2791657 Y CN 2791657Y CN 200420097384 CN200420097384 CN 200420097384 CN 200420097384 U CN200420097384 U CN 200420097384U CN 2791657 Y CN2791657 Y CN 2791657Y
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- current
- main circuit
- power
- power supply
- energy feedback
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Abstract
The utility model provides a general simulation device for an electric load, which comprises two main circuits for a bridge voltage type converter. The DC side of the utility model and a capacitor are connected in parallel to form a main circuit for a power current generator and an energy feedback main circuit of a simulation load, wherein the AC output terminal of the power current generator is connected with a tested power supply through an inductor and a filter circuit, the AC output terminal of the energy feedback main circuit is connected with a supply mains through an inductor and a filter circuit, the power current generator is controlled by a current arithmetic unit and a current tracking controller which are instructed by the simulation load, and the energy feedback is controlled by a capacitor voltage controller arranged at the DC side, a sinusoidal signal generator and a current tracking controller. The utility model can be used not only for simulating electric loads but also for simulating some electric test devices, such as an experiment power supply for accumulator charging, etc. The tested power supply can be a voltage source abd can also be a passive circuit.
Description
(1) technical field
The utility model relates to a kind of electrical load analogue means.
(2) background technology
In the various electrical equipments, the alterating and direct current source apparatus occupies quite great proportion, as accumulator, ac-dc power supply, uninterrupted power supply (ups) Unity, inverter etc.These power-supply devices all need to connect actual electrical load its performance parameter are tested after design and assembly are finished, and test job is inconvenience very.In addition, in scientific research or experiment, also often need some special electrical loads in colleges and universities and scientific research institutions, as harmonic current, nonlinear load etc.
At present, the electrical load analogue means is divided into " DC electronic load " and " alternating current electronic load " two kinds, and the former is used for the system that tested power supply is a direct voltage source, and the latter is used for the system that tested power supply is an alternating-current voltage source.The patent No. provides a kind of " DC electronic load simulator " for the Chinese patent of CN1137388C, and its output current is made up of a power tube and control circuit, and electric current can not change direction.The patent No. provides a kind of " alternating current electronic load analogue means " for the Chinese patent of CN1137536C, form by two power tubes and control circuit and input voltage phase-shift circuit, can output leading, hysteresis and homophase are in the alternating current of input ac voltage, capacitive, perception and resistive AC load can be simulated, but harmonic wave or nonlinear load can not be simulated.In addition, existing " electronic load " do not possess energy feedback function, and the bearing power during the simulation resistive load is all absorbed by " electronic load ", and the heating problem of " electronic load " is difficult to solve when therefore being used for large-power occasions.
(3) summary of the invention
At the deficiencies in the prior art, the utility model provides a kind of electric loading general analog apparatus of simulating the electric load of various alternating current-direct currents.
The solution that the utility model adopts is:
Electric loading general analog apparatus comprises two bridge-type voltage source converter main circuits, and its DC side is in parallel with capacitor, has formed the power current generator main circuit and the energy feedback main circuit of fictitious load; The power current generator ac output end links to each other with tested power supply with filtering circuit by inductance, and energy feedback main circuit ac output end links to each other with power supply grid with filtering circuit by inductance; Power current generator makes it to power electric current that satisfies the fictitious load relation of tested power supply output by a fictitious load instruction current arithmetical unit and current tracing controller control; The energy feedback is by dc bus capacitor device, voltage controller, sinusoidal signal generator and current tracing controller control, make it to one of power supply grid output and the sinusoidal current of line voltage with frequency, the active power of fictitious load device " absorption " is fed back to electrical network, and holding device output power factor is ± 1.
Fictitious load instruction current arithmetical unit goes out current instruction value according to the relational calculus of tested supply voltage and load current, promptly
i
ref(t)=f(e(t))
E in the formula (t) represents tested supply voltage, i
Ref(t) expression fictitious load current instruction value, f (.) represents its funtcional relationship.This current instruction value can be random waveform signals such as DC quantity, of ac, non-linear and harmonic wave, also can be any specification signal with tested independent of power voltage.Current tracing controller is according to the instruction current value and the output of the error control between the outputting inductance electric current pulse of the output of current operator device, and the switching power tube by in the driving circuit power controlling current feedback circuit main circuit makes inductive current trace command electric current.Filtering circuit is used for the switch harmonic composition of filtering output current.Main circuit dc bus capacitor device voltage controller is by the difference control of condenser voltage set-point and its detected value, and the amplitude and the polarity of power supply electric current is controlled in its output.The sinusoidal current generator obtains and the sinusoidal signal of power supply grid voltage with the frequency homophase, behind this signal and the capacitance voltage controller output multiplication, obtain energy feedback current instruction value, then by the switching power tube in the current tracing controller control energy feedback main circuit.
The utility model adopts modern power electronics technology and microelectric technique to realize a kind of power current generator.This power electric current can accurately the trace command current signal, therefore can simulate electric load of various alternating current-direct currents and testing equipment.
Electric loading general analog apparatus of the present utility model is able to programme, but its power two-way flow therefore not only can simulate electrical load, and can simulate some electrical test equipments, as the charge in batteries experiment power supply etc.Can export programmable current to passive load, therefore tested power supply can be a voltage source, also can be a passive electric circuit.
(4) description of drawings
Fig. 1 is the single-phase electric loading general analog principle of device of a utility model block diagram.
Fig. 2 is the utility model power current generator part control principle block diagram.
Fig. 3 is the utility model energy feedback part theory diagram.
Fig. 4 is the utility model power current generator current tracking error waveform synoptic diagram.
Fig. 5 is the utility model current tracking waveform synoptic diagram figure.
Fig. 6 is the utility model analog DC varying duty current waveform legend.
Fig. 7 is the utility model analog AC harmonic load current waveform legend.
Local schematic diagram when Fig. 8 is the utility model band power frequency isolating transformer.
Local schematic diagram when Fig. 9 is the utility model band high-frequency isolation transformer.
Among the figure, 1. tested power supply, 2. telefault, 3. switching frequency wave filter, 4. fictitious load power current generator part main circuit, 5. energy feedback part main circuit, 6. telefault, 7. power frequency isolating transformer, 8. power supply, 9. switching frequency wave filter, 10. the main circuit direct current is surveyed energy-storage capacitor, 11. fictitious load current reference value arithmetic element, 12. fictitious load current tracking control modules, 13. energy feedback control modules, 14. power switch pipe M1~M4 driver, 15. power switch pipe M5~M8 driver, 16a~16d. power switch pipe, 18a~18d. power switch pipe, 17a~17d. Ultrafast recovery diode (or in power switch pipe, including), 19a~19d. Ultrafast recovery diode (or in power switch pipe, including), 20. totalizers, 21. Schmidt's comparers, 22. the stagnant ring arithmetical unit of Schmidt's comparer, 23. zero-crossing comparator, 24. sine-wave generators, 25. totalizers, 26.PID regulator, 27. multiplier, 28. totalizers, 29. Schmidt's comparers, 30. high-frequency isolation transformer, 31. the bidirectional power DC/DC transducer that the band high-frequency transformer is isolated, e is the terminal voltage of tested power supply 1, u
sBe power supply 8 terminal voltages, U
cFor the main circuit direct current is surveyed electric capacity 9 terminal voltages, i
eBe fictitious load electric current, i
L1Be the input current of fictitious load power current generator main circuit part 4, i
F1Be the electric current of wave filter 3, i
E2Be the electric current of power supply 8, i
L2Be energy feedback part main circuit 5 output currents, f () is given tested supply voltage and the mathematical relation between the fictitious load electric current, i
RefBe the fictitious load current instruction value, Δ i1 is command value i
RefWith actual value i
L1Between error, U
CrefBe the set-point of main circuit direct current survey capacitance voltage, I
M2Be energy feedback part current instruction value i
Ref2Amplitude, the square-wave signal that φ 0 is a power supply 8 after comparer 23 conversions, sin () is a sine-wave generator, i
SinFor with u
sSynchronous unit amplitude sinusoidal signal, i
Ref2Be energy feedback part current instruction value, Δ i2 is command value i
Ref2With actual value i
L2Between error, h1 is the stagnant ring of Schmidt's comparer 21, h2 is the stagnant ring of Schmidt's comparer 29, T
pBe M1 (M4) ON time, T
nBe M2 (M3) ON time, T
rBe switch periods, Δ i
rBe fictitious load instruction current i
RefAt a switch periods T
rInterior increment.
(5) embodiment
Fig. 1 has provided the single-phase electric loading general analog principle of device of the utility model block diagram.Current feedback circuit main circuit 4 and energy feedback main circuit 5 are two voltage-type bridge converters, and its DC side is in parallel with capacitor 10.Main circuit 4 links to each other with tested power supply 1 with filtering circuit 3 by inductance 2.Main circuit 5 links to each other with power supply 8 with filtering circuit 9 by inductance 6.This brachium pontis of transducer power switch up and down two be complementary, two at diagonal angle be synchronous, promptly M1 and M4 are synchronous, M2 and M3 are synchronous, M5 and M8 are synchronous, M6 and M7 are synchronous.At first calculate fictitious load current instruction value i according to tested supply voltage e by fictitious load current reference value arithmetic element 11 by given load relationship f (.)
Ref, by the control signal of fictitious load current tracking control module 12 output main circuits 4 power switch pipe 16a~16d, drive 16a~16d then by driver 14, make the fictitious load current i
L1Follow current command value i
Ref, after filtering, obtain required fictitious load current i
e
(1) generation that refers to of fictitious load current-order
Fictitious load current instruction value arithmetic element 11 built-in a part of typical simulation load relationship f (.) software real time algorithm or hardware computing circuits, as resistance R, inductance L, capacitor C, compound R-L-C, uncontrollable rectification, controlled rectification, the humorous waveform commonly used etc. that involves, the user only needs to revise its parameter and gets final product on this machine or host computer.In addition, the user also can provide loadtype and parameter with the method for schematic diagram or program at host computer.
(2) control of fictitious load current tracking and constant frequency stagnate and encircle prediction algorithm
Current tracking control has a lot of methods, the utility model to provide a kind of new constant frequency hysteresis current control algolithm example.
If fictitious load power current generator output current i
L1And instruction value i
RefBetween error delta i1 be:
Δi
1=i
ref-i
L1
During operate as normal, U is arranged
c>| e
Max|, promptly dc voltage is higher than tested supply voltage absolute value peak value.By the conducting of Δ i1 by Schmidt's comparer 21 power controlling switching tube M1~M4 with end, its control law is:
As Δ i
1>h1, M1 and M4 conducting (ON), M2 and M3 have by (OFF)
L
1di
L1/dt=e+U
c>0
Output current i
L1Approximately linear rises.
As Δ i
1During<-h1, M1 and M4 are arranged by (OFF), M2 and M3 conducting (ON),
L1di
L1/dt=e-U
c<0
Output current i
L1Approximately linear descends.Its error current waveform as shown in Figure 4, the current tracking waveform is as shown in Figure 5.
In order to make switch periods constant, arithmetical unit 22 realize the stagnating following constant frequency prediction algorithm of ring h1: because the switch periods time is very short, suppose that Uc and e are constant in a switch periods, i.e. their variation can be ignored, instruction current i
RefFor straight line changes, then get by Fig. 5:
t
p+t
n=T
r
If
Then
Therefore according to given switch periods Tr and voltage U c, e measured value, and current instruction value i
RefThe variation delta i in a switch periods
r, can prediction and calculation go out the stagnant ring h1 of next switch periods.Realize that by this ring that stagnates the control of Schmidt's comparer can make switching frequency keep constant.
Above-mentioned algorithm draws in the ideal case, and such as requiring L1 and voltage U c, the e measured value must be accurately, otherwise actual switch periods will have error.The present invention has adopted the closed-loop corrected technology of following a kind of new switch periods for this reason, the effectively influence that caused of compensating circuit parameter drift or variation:
α(k+1)=α(k)+β(T
r-T(k))
α(0)=1
In the formula, k represents this switch periods, and T (k) is this switch periods value of actual measurement, and β is a positive coefficient, and α is the correction coefficient of the stagnant ring of prediction.Formula (11) will change into:
(3) energy feedback control
The energy feedback partly is used for active power feedback grid that fictitious load is absorbed, and to make power factor by control be ± 1.Energy feedback control mainly realizes according to the voltage U c FEEDBACK CONTROL of dc bus capacitor device 10.When capacitor 10 absorbs when meritorious, its magnitude of voltage Uc can rise, and emits when meritorious when capacitor 10, and its magnitude of voltage Uc can descend.Can design a PID regulator 26 according to this rule, capacitance voltage set-point U
CrefImport as the PID regulator with the difference of capacitance voltage measured value Uc, it exports I
M2The steering order current i
Ref2Amplitude, the shape of this instruction current is by power supply 8 voltage u
sDecision is perhaps tried to achieve and power supply 8 voltage u by 23 among Fig. 3 and 24
sSinusoidal signal i with the frequency homophase
SinDecision.The control signal of energy feedback control module output power pipe 18a~18d drives 18a~18d by driver 15, makes the current i of main circuit 5
L2Follow current command value i
Ref2, after filtering, obtain the active current current i of power supply 8
E2
The energy feedback current tracking control examples that the utility model provides is made up of the computing unit 22 of the Schmidt's comparer 29 and the ring h2 that stagnates, has realized the constant frequency hysteresis current control of energy feedback part.
Fig. 8 and Fig. 9 are the embodiments of band isolating transformer of the present utility model.When electrical link (no electrical isolation) is arranged between tested power supply and the power supply, need to use this scheme.Fig. 8 adopts Industrial Frequency Transformer to isolate, and adopts power frequency isolating transformer 7 between power supply 8 and fictitious load device.Fig. 9 adopts high-frequency transformer to isolate, and increases a two-way high frequency power DC/DC transducer 31 between main circuit 4 and 5.
The example that the utility model provides is single-phase electric loading general analog apparatus, and its principle is equally applicable to the three-phase electric loading general analog apparatus.
Claims (3)
1. electric loading general analog apparatus is characterized in that: the power current generator main circuit and the energy feedback main circuit that comprise the fictitious load that DC side and capacitor by two bridge-type voltage source converter main circuits compose in parallel; Power current generator main circuit ac output end links to each other with tested power supply with filtering circuit by inductance, and energy feedback main circuit ac output end links to each other with power supply grid with filtering circuit by inductance; The power current generator main circuit is connected with a current tracing controller, and this current tracing controller is connected with a fictitious load instruction current arithmetical unit; Energy feedback main circuit also is connected with a current tracing controller, and this current tracing controller is connected with dc bus capacitor device, voltage controller and sinusoidal signal generator.
2. electric loading general analog apparatus according to claim 1 is characterized in that: be provided with Industrial Frequency Transformer between described this analogue means and the power supply.
3. electric loading general analog apparatus according to claim 1 is characterized in that: the bidirectional power DC/DC transducer that is provided with the band high-frequency transformer between described power current generator main circuit and the energy feedback main circuit.
Priority Applications (1)
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CN 200420097384 CN2791657Y (en) | 2004-10-29 | 2004-10-29 | Electric load general simulation device |
Applications Claiming Priority (1)
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CN 200420097384 CN2791657Y (en) | 2004-10-29 | 2004-10-29 | Electric load general simulation device |
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CN2791657Y true CN2791657Y (en) | 2006-06-28 |
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Cited By (8)
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CN105490313A (en) * | 2015-11-27 | 2016-04-13 | 许继电源有限公司 | AC/DC common electronic load |
CN105699912A (en) * | 2012-06-21 | 2016-06-22 | 九尊城网络科技(深圳)有限公司 | Power supply load test device |
CN105699913A (en) * | 2012-06-21 | 2016-06-22 | 九尊城网络科技(深圳)有限公司 | Power supply load test device |
CN105699911A (en) * | 2012-06-21 | 2016-06-22 | 九尊城网络科技(深圳)有限公司 | Power supply load test device |
CN105823990A (en) * | 2015-01-04 | 2016-08-03 | 成都锐成芯微科技有限责任公司 | Analog load for testing SOC power source |
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2004
- 2004-10-29 CN CN 200420097384 patent/CN2791657Y/en not_active Expired - Fee Related
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CN105699912A (en) * | 2012-06-21 | 2016-06-22 | 九尊城网络科技(深圳)有限公司 | Power supply load test device |
CN105699913A (en) * | 2012-06-21 | 2016-06-22 | 九尊城网络科技(深圳)有限公司 | Power supply load test device |
CN105699911A (en) * | 2012-06-21 | 2016-06-22 | 九尊城网络科技(深圳)有限公司 | Power supply load test device |
CN105699912B (en) * | 2012-06-21 | 2018-11-16 | 唐山尚新融大电子产品有限公司 | Power source loads test device |
CN105699911B (en) * | 2012-06-21 | 2018-11-06 | 浙江嘉昱达机械有限公司 | Power source loads test device |
CN105823990B (en) * | 2015-01-04 | 2018-11-09 | 成都锐成芯微科技有限责任公司 | A kind of fictitious load for testing SOC power supplys |
CN105823990A (en) * | 2015-01-04 | 2016-08-03 | 成都锐成芯微科技有限责任公司 | Analog load for testing SOC power source |
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CN105490313A (en) * | 2015-11-27 | 2016-04-13 | 许继电源有限公司 | AC/DC common electronic load |
CN105490313B (en) * | 2015-11-27 | 2018-11-20 | 许继电源有限公司 | A kind of alternating current-direct current shared electron load |
CN106291012A (en) * | 2016-08-26 | 2017-01-04 | 深圳市伊力科电源有限公司 | Programmable DC power supply realizes system and method |
CN116626530A (en) * | 2023-07-24 | 2023-08-22 | 中国人民解放军空军预警学院 | High-power voltage stabilizing source fault detection method and system based on double channels |
CN116626530B (en) * | 2023-07-24 | 2023-10-03 | 中国人民解放军空军预警学院 | High-power voltage stabilizing source fault detection method and system based on double channels |
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Legal Events
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C17 | Cessation of patent right | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20060628 Termination date: 20091130 |