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LHXX-10XXX SERIES
5-25W, AC-DC CONVERTER
LH---- are high efficiency green power modules with various packaging provided by Mornsun. The features of this series are: wide input voltage, DC and AC all in one, high efficiency, high reliability, low loss, safety isolation etc. They are widely used in industrial, office and civil equipments. EMC and safety standards meet international standards IEC61000 UL60950and IEC60950, and Multi-certificate is in processing.
PRODUCT FEATURES
1. Universal Input :85 ~ 264VAC,50/60Hz 2. AC and DC all in one (input from the same terminal) 3. Low Ripple and Noise 4. Overload protection and short circuit protection 5. High efficiency, High power density 6. Low loss, green power 7. Multiple models available 8. industrial level specifications 9. 3 years warranty
MODEL SELECTION
LH10-10B24
Output Voltage Output St yle Input Voltage I solation Voltage Rated Pow er Package St yle Product Series
PRODUCT PROGRAM
Approval UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE Model LH05-10B03 LH05-10B05 LH05-10B09 LH05-10B12 LH05-10B15 LH05-10B24 LH05-10A05 LH05-10A12 LH05-10A15 LH05-10A24 LH05-10C0505-01 LH05-10C0512-01 LH05-10C0515-01 LH05-10C0524-01 LH05-10D0505-01 LH05-10D0512-01 LH05-10D0515-01 LH05-10D0524-01 UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE LH10-10B03 LH10-10B05 LH10-10B09 LH10-10B12 LH10-10B15 LH10-10B24 LH10-10A05 LH10-10A12 LH10-10A15 LH10-10A24 LH10-10C0505-04* LH10-10C0512-02 LH10-10C0515-02 LH10-10C0524-01* UL/CE UL/CE UL/CE UL/CE LH10-10D0505-02 LH10-10D0512-02 LH10-10D0515-02 LH10-10D0524-02 6.6W Package Power 4W Output (Vo1/Io1) 3.3V/1250mA 5V/1000mA 9V/550mA 12V/420mA 15V/330mA 24V/230mA +5V/500mA +12V/210mA +15V/160mA +24V/100mA 5V/800mA 5V/600mA 5V/600mA 5V/600mA 5V/900mA 5V/750mA 5V/700mA 5V/600mA 3.3V/2000mA 5V/2000mA 9V/1100mA 12V/900mA 15V/700mA 24V/450mA +5V/1000mA +12V/450mA +15V/350mA +24V/200mA 5V/1200mA 5V/1000mA 5V/900mA 5V/1000mA 5V/1800mA 5V/1500mA 5V/1400mA 5V/1000mA -5V/1000mA -12V/450mA -15V/350ma -24V/200ma 5V/400mA 12V/200mA 15V/200mA 24V/100mA 5V/200mA 12V/200mA 15V/200mA 24V/200mA 50mV 78 -5V/500mA -12V/210mA -15V/160mA -24V/100mA 5V/100mA 12V/100mA 15V/80mA 24V/50mA 5V/100mA 12V/100mA 15V/100mA 24V/100mA 70 Output (Vo2/Io2) Ripple and Noise (Typ.) Efficiency (%)(Typ.) 70
48.5X36X20.5mm
5W
50mV
76
55X45X21.0mm
10W
50mV
78
The copyright and authority for the interpretation of the products are reserved by Mornsun
Specifications subject to change without notice. LH** B/4-2008 Page 1 of 5
Approval UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE UL/CE
Model LH15-10B03 LH15-10B05 LH15-10B09 LH15-10B12 LH15-10B15 LH15-10B24 LH15-10B48 LH15-10A05 LH15-10A12 LH15-10A15 LH15-10C0505-05 LH15-10C0512-02 LH15-10C0515-02 LH15-10C0524-01* LH15-10D0505-08 LH15-10D0512-04 LH15-10D0515-03* LH15-10D0524-02
Package
Power 9.9W
Output (Vo1/Io1) 3.3V/3000mA 5V/2800mA 9V/1600mA 12V/1250mA 15V/1000mA 24V/625mA 48V/320mA +5V/1500mA +12V/650mA +15V/500mA 5V/2000mA 5V/2000mA 5V/1800mA 5V/2000mA 5V/2200mA 5V/2000mA 5V/2000mA 5V/2000mA 3.3V/4100mA 5V/3500mA 12V/1600mA 15V/1300mA 24V/850mA +5V/2000mA +12V/830mA +15V/650mA
Output (Vo2/Io2)
Ripple and Noise (Typ.)
Efficiency (%)(Typ.) 73
50mV
80
62x45x22.5mm
15W
-5V/1500mA -12V/650mA -15V/500mA 5V/500mA 12V/200mA 15V/200mA 24V/100mA 5V/800mA 12V/400mA 15V/300mA 24V/200mA
UL/CE UL/CE UL/CE UL/CE UL/CE
LH20-10B03 LH20-10B05 LH20-10B12 LH20-10B15 LH20-10B24 LH20-10A05 LH20-10A12 LH20-10A15 LH20-10C0505-05* LH20-10C0512-04 LH20-10C0515-03 LH20-10C0524-02 LH20-10D0505-10* LH20-10D0512-06 LH20-10D0515-05* LH20-10D0524-03 70x48x23.5mm 20W
-5V/2000mA -12V/830mA -15V/650ma 5V/500mA 12V/400mA 15V/300mA 24V/200mA 5V/1000mA 12V/600mA 15V/500mA 24V/300mA 50mV 82
5V/2500mA 5V/2000mA 5V/2000mA 5V/2000mA 5V/3000mA 5V/2500mA 5V/2500mA 5V/2500mA 5V/4100mA 12V/2100mA 15V/1600mA 24V/1100mA 48V/500mA
UL/CE UL/CE UL/CE UL/CE UL/CE
LH25-10B05 LH25-10B12 LH25-10B15 LH25-10B24 LH25-10B48
70x48x23.5mm
25W
50mV
85
Remarks : 1. Ripple and Noise were measured by the method of parallel lines; o 2. Unless otherwise specified, all specifications above are measured at rated input voltage and rated output load, Ta=25 C, humidity < 75%; 3. All specifications stated in this datasheet are subject to the above listed models only. For specifications of non-standard models, please contact our technical support team. 4. Model numbers marked with"*" are in developing.
INPUT SPECIFICATIONS
Input voltage range Input frequency Input current LH05 models LH10 models LH15 models LH20 models LH25 models LH05 models LH10 models LH15 models LH20/LH25 models External input fuse(recommended) LH05 models LH10/LH15 models LH20/LH25 models 85 ~ 264VAC, 47 ~ 63Hz 110VAC 120mA , 230mA , 250mA , 330mA , 420mA , 110VAC 10A, typ 10A, typ 10A, typ 16A, typ typ typ typ typ typ 230VAC 70mA , typ 120mA , typ 140mA , typ 180mA , typ 230mA , typ 230VAC 20A, typ 20A, typ 20A, typ 30A, typ 120 ~ 370VDC
Inrush current
1A/250V slow blow 2A/250V slow blow 3.15A/250V slow blow
The copyright and authority for the interpretation of the products are reserved by Mornsun
Specifications subject to change without notice. LH** B/4-2008 Page 2 of 5
OUTPUT SPECIFICATIONS
Voltage set accuracy Input variation Load variation (10-100%) Single output models Dual output models (balanced load) Isolated triple output (balanced load) Isolated and separated twin output (balanced load) 2% 0.5% 1.5% (main output) (main output) (supplement output)
1% 2% Vo1 3% Vo2 5% Vo1 3% Vo2 5%
(main output) (supplement output) (main output) (supplement output)
Minimum load
single output models Dual output models Isolated and separated twin output Isolated triple output 20MHz Bandwidth
0% 10% (main output) 10% (main output) 10% (main output) 100mV 110% IO (main output)
Ripple& noise(p-p) Short circuit protection Over current protection Over output voltage protection
Continuous, and auto resume
3.3 / 5VDC models 9VDC models 12 / 15VDC models 24VDC models 48VDC models
6.5VDC 12VDC 20VDC 30VDC 60VDC
COMMON SPECIFICATIONS
Temperature ranges Operating : Power derating LH20-10B05 Storage: Case temperature: Hold-up time Humidity (non condensing) (Vin=230VAC) above 55C: above 50C: -25C ~ +70 C 3.75% / C 2.25% / C -25C ~ +105 C +90C max 80ms(typ) 85%(max) 0.02%/C (main output) 0.15%/C (supplem ent output) 150kHz 78% typ 3000VAC/1Min 0.3mA RMS typ. 230VAC/50Hz EN55022, level B Electrostatic discharge ESD RF field susceptibility Electrical fast transients/bursts on mainsline Surge IEC/EN 61000-4-2 level 3 IEC/EN 61000-4-3 IEC/EN 61000-4-4 level 3 IEC/EN 61000-4-5 level 3 6KV/8KV 2KV 1KV / 2KV max
Temperature coefficient Switching frequency Efficiency I/O-isolation voltage Leakage current EMI/RFI conducted EMC compliance
Safety standards Safety approvals Safety Class Case material Install MTBF
IEC60950,EN60950,UL60950 EN60950, IEC60950,UL60950 CLASS 1 CLASS 2 While LH15) UL 94V-0 PCB >200,000h @25C
The copyright and authority for the interpretation of the products are reserved by Mornsun
Specifications subject to change without notice. LH** B/4-2008 Page 3 of 5
TYPICAL APPLICATIONS
LH**-10B**( single Output)
F u se NT C
L N L N -Vo +Vo C1 C2 TVS1 RL
LH**-10A**(Dual output)
Fuse L N NT C L N +Vo Co m -Vo C1 C 2 TVS1 RL
C3 C 4 TVS2 R L
LH**-10D**(Isolate Twin Output)
F use NT C L N
LH**-10C**(Triple Output)
L N
Vo1
+
C1 C2 T V S 1 RL
L
F u se
NTC L
+Vo1 -Vo1 +Vo 2 N Co m
C 1 C2 TVS1 R L
+
Vo2
C3
C4 TVS2 RL
N
-
C3 C4 T V S 2 RL
-Vo2
C5
C6 TVS3 R L
EXTERNAL CAPACITORS TYPICAL VALUE(Unit: F)
MODEL
LH05-10B03 LH05-10B05 LH05-10B09* LH05-10B12 LH05-10B15 LH05-10B24 LH05-10A05 LH05-10A12 LH05-10A15 LH05-10A24 LH05-10C0505-01 LH05-10C0512-01 LH05-10C0515-01 LH05-10C0524-01 LH05-10D0505-01 LH05-10D0512-01 LH05-10D0515-01 LH05-10D0524-01 LH10-10B03 LH10-10B05 LH10-10B09 LH10-10B12 LH10-10B15 LH10-10B24 LH10-10A05 LH10-10A12 LH10-10A15 LH10-10A24 LH10-10C0505-04 LH10-10C0512-02 LH10-10C0515-02 LH10-10C0524-01 LH10-10D0505-02 LH10-10D0512-02 LH10-10D0515-02 LH10-10D0524-02
C1
330 330 120 120 68 68 120 68 47 10 220 120 120 120 220 220 120 120 470 330 120 120 120 68 220 120 47 33 220 220 220 220 220 220 220 220
C3
C5
MODEL
LH15-10B03 LH15-10B05 LH15-10B09 LH15-10B12 LH15-10B15 LH15-10B24 LH15-10B48
C1
680 680 470 220 220 68 33 470 220 120 470 470 470 470 470 470 470 470 330 330 220 220 220 470 120 68 330 330 330 330 330 330 330 330 330 330 330 120 68
C3
C5
120 68 47 10 22 22 22 22 22 22 22 22 22 22 22 22
LH15-10A05 LH15-10A12 LH15-10A15 LH15-10C0505-05 LH15-10C0512-02 LH15-10C0515-02 LH15-10C0524-01 LH15-10D0505-08 LH15-10D0512-04 LH15-10D0515-03 LH15-10D0524-02 LH20-10B03 LH20-10B05 LH20-10B12 LH20-10B15 LH20-10B24
470 220 120 220 120 120 47 470 220 120 47 220 120 120 47
220 120 47 33 120 68 47 47 68 68 47 47 120 68 47 47
LH20-10A05 LH20-10A12 LH20-10A15 LH20-10C0505-05 LH20-10C0512-04 LH20-10C0515-03 LH20-10C0524-02 LH20-10D0505-10 LH20-10D0512-06 LH20-10D0515-05 LH20-10D0524-03 LH25-10B05 LH25-10B12 LH25-10B15 LH25-10B24 LH25-10B48
470 120 68 220 120 120 47 330 220 220 120 220 120 120 47
Remark 1. Output filtering capacitors C1, C2 and C3 are electrolytic capacitors, It is recommended to use high frequency and low impedance electrolytic capacitors. For capacitance and current of capacitor please refer to manufacture's datasheet. Voltage derating of capacitor should be 80% or above. C2,C4,C6 are use to filter high frequency noise. TVS is recommended component to protect post-circuits (when converter fails). 2. External input NTC is recommended to use 5D-9 ( Only LH10 models and LH15 models)
The copyright and authority for the interpretation of the products are reserved by Mornsun
Specifications subject to change without notice. LH** B/4-2008 Page 4 of 5
TYPICAL EFFICIENCY CURVE
Vin=230Vac
95 90 85 90 88
Load=100%
LH05-10B05
E fficiency (%)
LH05-10B05 LH05-10B24 LH10-10B05 LH10-10B24 LH15-10B05 LH15-10B24 LH20-10B05 LH20-10B24
LH05-10B24 LH10-10B05 LH10-10B24 LH15-10B05 LH15-10B24 LH20-10B05 LH20-10B24
86 84 82 80 78 76 74 72 70 85 120 240 264
Efficiency(%)
80 75 70 65 60 55 50 10% 20% 30% 40% 50% 60% 70% 80% 90% 100%
Load
Input voltage (Vac)
INPUT VOLTAGE VS LOAD
Load (%) 100 80 60 40 20 70 85 100 240 264
TEMPERATURE VS LOAD
Load (%) 100 80 60 40
-25
-10
0 Te mperat ure( C)
55
70
Input voltage (Vac)
*Note: When input DC,
Vdc=1.414Vac-20Vdc.
PARALLEL LINES MEASURE
Copper sheet
L
Fuse
3 +Vo
AC-DC
N
2 -Vo
C1
C2
Load
Connect Oscillograph Probe
2 5.4m m
2 5.4m m
C1:10F
C2:0.1F
OUTLINE AND DIMENSIONS
First Angle Projection
OUTLINE AND DIMENSIONS 3 8 7 6 5 4 Trim A
N0. A B C D E F G I LH05 12.5 48.5 40.5 4.0 16.0 36.0 20.5 4.0 LH10 17.5 55.0 47.0 5.0 20.0 45.0 21.0 4.0 LH15 17.5 62.0 54.0 5.0 20.0 45.0 22.5 4.0 LH20 20.0 70.0 62.0 5.75 23.0 48.0 23.5 4.0 LH25 20.0 70.0 62.0 5.75 23.0 48.0 23.5 4.0
A
1
I
C B
I
D
2
(Bottom vie w)
E F
FOOTPRINT DETAILS
Pin LHXX-10B AC(N) AC(L) -Vo No Pin No Pin No Pin +Vo Trim** LHXX-10A AC(N) AC(L) -Vo No Pin COM No Pin +Vo No Pin LHXX-10C AC(N) AC(L) -Vo1 +Vo1 -Vo2 COM +Vo2 No Pin LHXX-10D AC(N) AC(L) -Vo1 +Vo1 No Pin -Vo2 +Vo2 No Pin
(Side vie w)
1 2 3 4 5 6 7 8
Trim
H
G
There is no Pin 1"
" on LH15-10BXX.
Note: Unit:mm(inch) Pin section:1.00mm(0.039inch) Pin Length(H): 6.00mm( 0.236inch) Pin tolerances: 0.1mm( 0.004inch) General tolerances: 0.5mm( 0.020inch)
Trim**:Only For LH20/25-10BXXSeries
MODLES WEIGHT
WEIGHT (TYP) LH05 50g LH10 70g LH15 80g LH20 120g LH25 120g
The copyright and authority for the interpretation of the products are reserved by Mornsun
Specifications subject to change without notice. LH** B/4-2008 Page 5 of 5
AC-DC Converter Application Guidelines
1. Foreword
The following guidelines should be carefully read prior to converter use. result in the risk of electric shock, damaging the converter, or fire.
11 Risk of Injury A. B.
Improper use may
To avoid the risk of burns, do not touch the heat sink or the converter 's case.
Do not touch the input terminals or open the case and touch internal components, which cold result in electric shock or burns. C. When the converter is in operation, keep hands and face at a distance to avoid potential injury during improper operation.
12 Installation Advice
Please make sure the input terminals and signal terminals are properly connected in accordance with the stated datasheet requirements. B. To ensure safe operation and meet safety standard requirements, install a slow blow fuse at input of the converter.
A. C. Installation and use of AC/DC converters should be handled by a qualified
professional. D. AC/DC converters are used in the primary transmission stage of a design and thus, should be installed in compliance with certain safety standards. E. Please ensure that the input and output of the converter are incorporated into the design out of the reach of the end user. The end product manufacturer should also ensure that the converter is protected from being shorted by any service engineer or any metal filings. F. The application circuits and parameters shown are for reference only. All parameters and circuits are to be verified before completing the circuit design.
G. These guidelines are subject to change without notice; please check our website for
updates.
2. General AC-DC Converter Applications
2.1 Basic Application Circuit
In Figure 1, F1 refers to the input fuse. Proper fuse selection should be a safety agency approved, slow blow fuse. Selection of the proper fuse rating is necessary to ensure power converter and system protection (potential failure if the rating is too high) and prevent false fuse blowing (which could happen if the rating is too low). Below is the formula to calculate the proper rating:
I = 3 x Vo1 x Io1 / / Vin(min.) Vo1 = output voltage Io1 = output current; = the converter's efficiency;
Vin(min) = the minimum input voltage Futher circuit notations: NTC is a thermistor. CY and CX are safety capacitors. C1 is a high frequency ceramic capacitor or polyester capacitor, 0.1F/50V. C2 is output filtering high frequency aluminum electrolytic capacitor. Select a 220F rating if the output current is greater than 5A, or a 100F rating if the output current is less than 5A. The insulation voltage should be derated to less than 80% of rated value. For dual or triple output converters, the circuit of input side remains the same and the outputs should be considered independently in component selection (see Figure 3). The application circuit shown in Figure 1 is typical application circuit, whereby all MORNSUN products will meet EMI Class B, and Class 3 lightening strike and surge testing (see component datasheets for more details). To comply with more stringent EMC testing, additional filtering should be incorporated. See Figure 2 for a suggested filtering circuit.
For multi-output converters, the main output is typically a fully regulated output. If the end application requires critical regulation on the auxiliary output(s), a linear regulator or other regular should be added after the converter. (Note: Some MORNSUN converters have built in linear regulators; please contact our Technical Department for details).
3. AC-DC Converter Safety Related Design Notes
3.1 Marking Requirements Wherever, there are fuses, protective grounds, or switches, clear symbols should be indicated according safety standards. Touchable dangerous high voltage and energy sources should be marked with "Caution!" indications. 3.2 Input Cable Requirements: Input cables of L, N and E should be brown, blue and yellow/green cables, respectively. Ensure that the ground cable (yellow & green cable) of Type I devices (those that rely on basic insulation and protection ground to avoid electric shock) are securely connected to the ground, and the earth resistance is lower than 0.1 3.3 Clearance and Creepage For Type I devices, ensure: L and N are in front of the fuse. The clearance distance between the input and the metal case is above 2mm and creepage is above 2.5mm. For Type II devices (those that rely on strengthened insulation or double insulation to avoid electric shock) ensure: L and N are in front of the fuse The clearance distance between the input and the metal case is above 2mm and creepage is above 2.5mm. The clearance between the input and the metal case or SELV is above 4mm, and creepage of that is above 5mm. 3.4 Input energy If the input capacitor is large, a discharge resistor may be added to ensure that, after disconnect, the voltage held between Input L, N, and the protective ground will be discharged to 37% of its maximum value or below. In Figure 2, R1 is the discharge resistor.
4. Heat Dissipation in AC/DC Converter Module Applications
Trends toward higher density in AC/DC module designs make heat dissipation an important concern. The effect of heat on the electrolytic capacitor is of particular concern, as the life of such capacitors can be drastically reduced when operated in a constant high temperature environment, leading to a higher potential for failure. Proper handling of heat will increase the life of the converter and surrounding components, thus lowering risk of failures. Some
suggestions for handling dissipated heat are summarized, below: (1) Ambient Air Cooling For miniature and high power density converters, free air cooling is recommended, mainly due to cost and space concerns. Heat dissipates to the ambient air through the converter case or exposed surfaces. Heat may also dissipate to ambient air if there is a gap between the converter and the PCB. Heat dissipates from the converter case and exposed surfaces to PCB by radiation. Heat conducts through terminals (pins) to PCB.
In such applications, please pay particular attention to: A. Air Flow - Because the heat dissipation is mainly through convection and radiation, the converter needs an environment with good air flow. It may be helpful to design heat dissipation venting holes throughout the end product, near the converter 's location. For best convection cooling, ensure that air flow is not blocked by large components B. Layout of Heat Generating Components - In most applications, the AC/DC converter is usually not the only heat generating component. It is recommended to keep a good distance between each heat generating component to minimize heat dissipating clusters. C. PCB Design - The PCB, which the power converter is assembled on, is not only a base to mount the converter, but also acts as a heat sink for it, therefore heat dissipation should be considered in PCB layout. We recommend extended the area of the main copper loop and decrease the component density on the PCB to improve the ambient environment. (2) Heat Sinks When free air convection is not sufficient enough, we recommend the use of a heat sink for further cooling. As the converters are filled with heat conductive silicon or epoxy, the heat distribution in converter is even and it radiates from the converter to the air. The efficiency of this convection is dependent on the size of the surface area of the converter. The use of heat sinks is a practical method to add surface area and improve the convection. There are many kinds of heat sinks available in the market. MORNSUN recommends considering the following factors in selecting a heat sink:
The heat sink should be made of a good heat conducting material, such as aluminum and copper. The larger the surface area, the better the radiation. Therefore, heat sinks usually have a ridged surface or special coatings to make a larger surface area. Use the longest and thickest possible heat sink for best convection. Heat sinks are best attached to the converter's surface, where the difference in temperature between the surface and the ambient is largest. The use of heat conductive material between the heat sink and the converter 's surface to make a better contact and to improve heat conductance is suggested. To avoid case distortion, please do not affix the heat sink too firmly to the converter case.
(3) Forced Air Cooling In some systems, where a heat sink does not effectively reduce the ambient temperature, a fan is used to improve the heat radiation. Fans can lower the surface temperature of the converter, but large fans also occupy extra space in the system. It is important to select a suitable fan size, where the speed of the fan will determines how effective it is. The faster the speed, the better the effect on reducing radiated heat. As high speed will also cause increased noise, there is a need to balance the choice between the how effective the fan is against how much audible noise it generates. A long, rectangular shaped AC/DC converter should use a horizontal fan, and channeled heat sinks should use vertical fans, in order to encourage air flow through the channels.
5. Input Under Voltage Impact
5.1 Block Diagram of AC/DC Converter
5.2 Impact to Converter Reliability The input voltage range of MORNSUN's AC/DC converters is 85~264VAC or 120~370VDC. When the converter is operated within the rated input voltage range, the output current can be used up to the maximum rated specification. The total output power is Io x Vo.
If the converter is operated with an input voltage that is under the rated voltage, offering the same output power of I o x Vo , causes the current (Is) at the transistor (S) to be increased. Long term operation under this condition will damage the transistor (S).
5.3 Input Voltage vs Load Capability (LD03-00B24)
30 25 Output voltage(V) 20 15 70VAC 10 5 0 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% 110% 120% 130% 140% 65VAC 60VAC Load(%) 85VAC 80VAC 75VAC
Load 85VAC 80VAC 75VAC 70VAC 65VAC 60VAC
0% 23.85 23.83 23.83 23.83 23.83 23.83
10% 23.82 23.82 23.83 23.83 23.83 23.83
20% 23.79 23.82 23.83 23.83 23.83 23.83
30% 23.77 23.83 23.83 23.83 23.83 23.83
40% 23.74 23.82 23.82 23.82 23.82 23.82
50% 23.71 23.82 23.82 23.82 23.82 23.51
60% 23.68 23.81 23.82 23.81 23.82 17.86
70% 23.65 23.81 23.81 23.79 23.8 14.13
80% 23.61 23.81 23.77 19.96 19.6 10.52
90% 23.58 23.8 20.29 16.44 15.67 8.28
100% 23.57 21 16.65 13.32 12.46 0
110% 23.19 18.5 14.02 11.14 9.57
120% 19.2 15 10.98 8.79 7.65
130% 14.7 13 9.39
140% 11 10.5 7.04

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