精品国产一区二区亚洲人成毛片_日韩视频在线观看免费_成年人一级黄色片_久久国产精品免费_国产一区二区三区精品视频_亚洲另类色综合网站_黄色美女网站在线观看

Chinese

Advisory hotline: 4008-557-528

hot key words: Dongguan skived fin heat sink vendor Shenzhen skived fin heat sink vendor Dongguan PV inverter heat sink PV inverter heat sink vendor Jiangsu skived fin heat sink vendor Custom SVG heat pipe thermal module

Inverters are also called power regulators. The process of converting DC power into AC power is called invert. The circuit that can realize the inverting function is called an inverter circuit. A device that can realize the inverting process is called an inverting device or inverter. In a solar energy generation system, the inverter efficiency is an important factor that determines the solar cell capacity and the storage battery capacity. The breakdown of PV inverter will cause the PV system to shut down and this directly leads to the loss of power generation. Therefore, high reliability is an important technical indicator for PV inverters.
The good cooling of PV inverters is an important criterion to ensure the high reliability of its operation. Therefore, it is recommended to carry out thermal simulation in the beginning of PV inverter's design stage and this has become the first issue to be considered by PV inverter manufacturers. As one of the professional high power cooling manufacturers in China, Winshare Thermal has an outstanding thermal design and development team, which owns the capability of carrying out reliable thermal simulation and testing. We have collaborated with several domestic and overseas PV inverter manufacturers on the cooling technology for inverters and have been supplying services and supports with our professional cooling technology.
Schematic of the simulation model and parameters (1):
Ambient temperature: 55?C; reactor heat load: 700W
 
Assuming a system impedance of 80 Pa, the fan curve through the heat sink can be adjusted as follows.
Schematic of the simulation model and parameters (2):




The top left figure is the schematic of the internal structure and heat-dissipating devices of the Infineon IGBT
Diode:59W; IGBT:124.5W; Total:1100WW;
Assuming the thermal interface material is 0.15mm thick with a thermal conductivity of K=3W/m*K
 
Schematic of the simulation model of the heat sink solution and its parameters:
Heat sink parameters:
Dimensions: W236*L200*H304mm
Fin :
Thickness: 0.6mm
Fin gap: 3.0mm
Fin count: 77fins
Heat pipe parameters:
DD8 sintered tube or groove structure;
24 pcs of U-shaped heat pipes (single-layer layout) and 48 pcs of L-shaped heat pipes (dual-layer layout) are used
4258 low-temperature solder paste is used for soldering;
Base: Al plate + copper plate (IGBT heat source area)
The design with a single layer of heat pipes has a lower cost and higher cooling performance as compared to dual layers of heat pipes.
 
Schematic of the simulated cross-sectional pressure distribution in the thermal module:
Schematic of the simulated cross-sectional velocity distribution in the thermal module:
 
Schematic of the simulated cross-sectional temperature distribution in the thermal module:
Schematic of the simulated temperature distribution on the top layer of heat pipes:

(The temperature difference between both ends of the heat pipe is 5.7℃, which meets the practical criteria for heat pipes.)

 
Schematic of the simulated temperature distribution on the bottom layer of heat pipes:

(The temperature difference between both ends of the heat pipe is 9℃, which is slightly higher than the real scenario. The actual performance of the heat pipes will be better than those configured in this analysis.)

Schematic of the simulated temperature distribution on the bottom side of the heat sink:
 

(The actual air temperature entering the heat sink is ~57.1?C and the maximum temperature at the heat sink bottom is 85.1?C with a temperature difference of 28?C according to the theoretical analysis.)

 
Schematic of the simulated temperature distribution on the NTC module:
Schematic of the fan operating point:
 

(The temperature difference between both ends of the heat pipe is 9℃, which is slightly higher than the real scenario. The actual performance of the heat pipes will be better than those configured in this analysis.)

Summary of the simulation data of the cooling solution for the PV inverter:

Solution

Ta

Power

H.S
Tb max

H.S
DT

NTC1

NTC2

NTC3

Fan
working point

Al base+
copper block

55

IGBT/3pcs
1100W/each
Reactor
700W

85.1

28

87.6

88.1

87.5

1127.5
m^3/Hr
215Pa

Assuming a system air inlet temperature of 55?C, the temperature of the air leaving the reactor is 57.1?C. Assuming a thermal interface material of 0.15mm thick with a thermal conductivity of K=3W/m*K is used.)

The voice of Winshare Thermal: credit and word

Winshare Thermal Ltd. (hereinafter referred to as Winshare Thermal) was founded in 2009. We specialize in the research and development, production and technical services of high power cooling solutions. We are devoted to becoming the leader in the thermal... [See details]

Copyright: Dongguan Winshare Thermal Ltd.

主站蜘蛛池模板: 久久久久日韩精品免费观看网 | 九九热国产精品视频 | 久久免费公开视频 | 久久综合九色综合97欧美 | 久久国产精品国语对白 | 日本性在线 | 亚洲欧洲日本在线观看 | 在线观看人成网站深夜免费 | 精品全国在线一区二区 | 激情视频网站在线观看 | 国产午夜免费视频片夜色 | 精品欧美亚洲韩国日本久久 | 毛片真人毛毛片毛片 | 波多野结衣国产一区二区三区 | 蜜桃视频m3u8在线观看 | 国产超爽人人爽人人做 | 国产啪精品视频网给免丝袜 | 日本高清视频www夜色资源网 | 久久99精品一久久久久久 | 麻豆精选传媒4区2021 | 日韩欧美在线观看视频一区二区 | 国产成人99精品免费视频麻豆 | 欧美一区二区三区视频 | 日本最新免费不卡二区在线 | 亚洲国产黄色 | 日本久久中文字幕 | 国产精品国产精品 | 欧美精品九九99久久在观看 | 国产在线手机视频 | 千人斩欧美图区 | 视频一区二区三区自拍 | 男人的午夜影院 | 人人看人人做人人爱精品 | 欧美乱大交xxxxx按摩v | 国产成人精品免费影视大全 | 国产欧美在线视频免费 | 麻豆视频免费看 | 玖玖玖传媒有限公司 | 九九九色 | 免费看精品黄线在线观看 | 在线看的成人性视频 |