1.5.4.2 Selection of Number of Unit

1.5.4.2 Selection of Number of Units
The installed capacity of Houay Por HPP will be 15,000kW, and it is to select 4 units 2X5, 000kW+2X2, 500kW. The details may be referred to relevant section concerning turbine.
1.5.5 Sediment Desilting Analysis and Backwater Calculation
1.5.5.1 Sediment Desilting Analysis of the reservoir
Houy Poy HPP is to be adopted low-gate headrace-type development, it is to build a dam near Ban Senvang on Xeset River to intake water (referred to as the main dam site), and build a low dam on Houay Por River to form a regulating reservoir (referred to as the saddle dam), soad to utilize the channel to divert water from Xeset river to Houay Por River for power generation.
The FSL of the reservoir of the main dam site is El.322.50m the river bottom U/S of the dam is at El.316.50m , the backwater hight of the gate dam is 6.0m, the rated head is 61m, the reservoir back water length is about 300m, the storage capacity under the FSL is 76,000 m3 (before silting), and the gradient of natural river channel in the reservoir area is 5%. The FSL of the reservoir of the saddle dam is El. 320.00m, the river bottom U/S of the dam is at El. 316.00m, the backwater height is 4.om, and the storage capacity under FSL is 135,000m3 (before silting). The storage capacity of the main dam site is relatively small and free of regulating capacity, with considerable sediment and a relatively large flood may still up the reservoir. Therefore, while using the reservoir it is to adopt the means of transient shutdown for desilting according to the incoming sediment of flood, so as to avoid sediment silting affecting normal intaking of the HPP.
The perennial average incoming suspended load the reservoir of Hoauy Por HPP is 104,000t, and the perennial average sediment contents is 199g/m3; The average incoming suspended load sediment in the reservoir during the flood season of May-October is 91,100t, the average sediment content is 427.45 g/m3, and the sediment during the flood season accounts for 87.5%. since the sediment silting rate of the reservoir area is relatively fast, thesediment control issue of headrace of headwork complex of the HPP is quite prominent. To prevent sediment from entering the water intake, maintaining storage capacity of the HPP is the main task for sediment design in this project. How Houay Por HPP may reduce abrasion of the turbine by sediment passing, so as to guarantee safe operation of the HPP, is also an engineering sediment issue to be solved.
According to sediment data analysis the quantities of sediment are mainly concentrated in a few peak floods. According to the statistics of runoff data the average number of days with daily average discharged large than 350m3 /s is 3 days and the percentage of sediment quatity is relatively large. Therefore, it is to select the peak flood discharge as 350m3/s the gate of the HPP is to be fully open and it is to shut down for desilting.
It is to adopt equilibrium gradient method to estimate the sediment silting of reservoir area of Houay Por HPP.
In desilting calculation of reservoir sediment it is to adopt one of the calculation methods and mathematic models suggested in Specification For Sediment Design of Hydropower and Water Conservancy Project- mathematic model of SUJSBED-II River sediment developed by Wuhan University.
The sediment silting of the reservoir area of the HPP is related to the U/S water inflow and incoming sediment, as well as terrain of the reservoir and operation means of HPP. According to the reservoir operation means proposed before, it is to adopt the mathematic model of USBED-II river sediment to calculate the sediment desilting process, the calculation results indicate that: the number of silting equilibrium years will be 50 years, the sediment silting in the reservoir will be 27,000m3, and the remaining storage capacity below FSL is 49,000m3.

1.5.4.2 Selection of Number of Units
The installed capacity of Houay Por HPP will be 15,000kW, and it is to select 4 units 2X5, 000kW+2X2, 500kW. The details may be referred to relevant section concerning turbine.
1.5.5 Sediment Desilting Analysis and Backwater Calculation
1.5.5.1 Sediment Desilting Analysis of the reservoir 
Houy Poy HPP is to be adopted low-gate headrace-type development, it is to build a dam near Ban Senvang on Xeset River to intake water (referred to as the main dam site), and build a low dam on Houay Por River to form a regulating reservoir (referred to as the saddle dam), soad to utilize the channel to divert water from Xeset river to Houay Por River for power generation.
The FSL of the reservoir of the main dam site is El.322.50m the river bottom U/S of the dam is at El.316.50m , the backwater hight of the gate dam is 6.0m, the rated head is 61m, the reservoir back water length is about 300m, the storage capacity under the FSL is 76,000 m3 (before silting), and the gradient of natural river channel in the reservoir area is 5%. The FSL of the reservoir of the saddle dam is El. 320.00m, the river bottom U/S of the dam is at El. 316.00m, the backwater height is 4.om, and the storage capacity under FSL is 135,000m3 (before silting). The storage capacity of the main dam site is relatively small and free of regulating capacity, with considerable sediment and a relatively large flood may still up the reservoir. Therefore, while using the reservoir it is to adopt the means of transient shutdown for desilting according to the incoming sediment of flood, so as to avoid sediment silting affecting normal intaking of the HPP.
The perennial average incoming suspended load the reservoir of Hoauy Por HPP is 104,000t, and the perennial average sediment contents is 199g/m3; The average incoming suspended load sediment in the reservoir during the flood season of May-October is 91,100t, the average sediment content is 427.45 g/m3, and the sediment during the flood season accounts for 87.5%. since the sediment silting rate of the reservoir area is relatively fast, thesediment control issue of headrace of headwork complex of the HPP is quite prominent. To prevent sediment from entering the water intake, maintaining storage capacity of the HPP is the main task for sediment design in this project. How Houay Por HPP may reduce abrasion of the turbine by sediment passing, so as to guarantee safe operation of the HPP, is also an engineering sediment issue to be solved.
According to sediment data analysis the quantities of sediment are mainly concentrated in a few peak floods. According to the statistics of runoff data the average number of days with daily average discharged large than 350m3 /s is 3 days and the percentage of sediment quatity is relatively large. Therefore, it is to select the peak flood discharge as 350m3/s the gate of the HPP is to be fully open and it is to shut down for desilting.
It is to adopt equilibrium gradient method to estimate the sediment silting of reservoir area of Houay Por HPP.
In desilting calculation of reservoir sediment it is to adopt one of the calculation methods and mathematic models suggested in Specification For Sediment Design of Hydropower and Water Conservancy Project- mathematic model of SUJSBED-II River sediment developed by Wuhan University.
The sediment silting of the reservoir area of the HPP is related to the U/S water inflow and incoming sediment, as well as terrain of the reservoir and operation means of HPP. According to the reservoir operation means proposed before, it is to adopt the mathematic model of USBED-II river sediment to calculate the sediment desilting process, the calculation results indicate that: the number of silting equilibrium years will be 50 years, the sediment silting in the reservoir will be 27,000m3, and the remaining storage capacity below FSL is 49,000m3.

0/5000

From: -

To: -

Results (Lao) 1: [Copy]

Copied!

1.5.4.2 ການຄັດເລືອກເອົາຈໍານວນຂອງຫນ່ວຍງານ
ທີ່ກໍາລັງຕິດຕັ້ງຂອງເຂື່ອນຫ້ວຍ Por HPP ຈະ 15,000kW, ແລະມັນແມ່ນເພື່ອຄັດເລືອກເອົາ 4 2x5 ຫນ່ວຍ, 000kW + 2x2, 500kW. ລາຍລະອຽດຂອງອາດຈະຫມາຍເຖິງພາກສ່ວນທີ່ກ່ຽວຂ້ອງຫັນກ່ຽວກັບການ.
155 ຕະກອນການວິເຄາະ Desilting ແລະ Backwater ການຄິດໄລ່
1.5.5.1 ຕະກອນການວິເຄາະ Desilting ຂອງອ່າງເກັບ
ຫ້ວຍ Poy HPP ແມ່ນໄດ້ຮັບການຮັບຮອງເອົາການພັດທະນາຕ່ໍາປະຕູຮົ້ວ, headrace ປະເພດ, ມັນແມ່ນການກໍ່ສ້າງເຂື່ອນໄຟຟ້າ ໃກ້ບ້ານ Senvang ສຸດ Xeset ນ້ໍານ້ໍາໄດ້ຮັບ (ຫມາຍເຖິງການເຂື່ອນຕົ້ນຕໍ), ແລະການກໍ່ສ້າງເຂື່ອນໄຟຟ້າຕ່ໍາໃນຫ້ວຍນ້ໍາ Por ເພື່ອປະກອບເປັນອ່າງເກັບຄວບຄຸມໄດ້ (ຫມາຍເຖິງການສ້າງເຂື່ອນໄຟຟ້າ saddle ໄດ້), soad ການນໍາໃຊ້ຊ່ອງທາງໃນການຫັນເອົານ້ໍາ ຈາກແມ່ນ້ໍາ Xeset ຮອດຫ້ວຍນ້ໍາ Por ສໍາລັບການຜະລິດພະລັງງານ.
FSL ຂອງອ່າງເກັບນຂອງເຂື່ອນຕົ້ນຕໍແມ່ນ El.322.50m ລຸ່ມແມ່ນ້ໍາ U / S ຂອງເຂື່ອນແມ່ນຢູ່ໃນ El.316.50m, ການ hight ນ້ໍາຂອງເຂື່ອນໄຟຟ້າປະຕູແມ່ນ 6.0m, ຫົວຫນ້າຈັດອັນດັບແມ່ນ 61m, ອ່າງເກັບຄືນຄວາມຍາວນ້ໍາແມ່ນກ່ຽວກັບ 300m, ຄວາມສາມາດໃນການເກັບຮັກສາພາຍໃຕ້ການ FSL ແມ່ນ 76,000 m3 (ກ່ອນ silting), ແລະລະດັບຊັ້ນຂອງຊ່ອງນ້ໍາທໍາມະຊາດໃນເຂດອ່າງເກັບນແມ່ນ 5%. FSL ຂອງອ່າງເກັບນຂອງເຂື່ອນ saddle ໄດ້ແມ່ນ El. 320.00m, ທາງລຸ່ມແມ່ນ້ໍາ U / S ຂອງເຂື່ອນແມ່ນຢູ່ El. 316.00m, ລະດັບຄວາມສູງນ້ໍາແມ່ນ 4.om, ແລະຄວາມສາມາດໃນການເກັບຮັກສາພາຍໃຕ້ການ FSL ເປັນ 135,000m3 (ກ່ອນ silting). ຄວາມອາດສາມາດເກັບຮັກສາຂອງເຂື່ອນຕົ້ນຕໍແມ່ນຂ້ອນຂ້າງມີຂະຫນາດນ້ອຍແລະບໍ່ເສຍຄ່າຂອງການຄວບຄຸມຄວາມອາດສາມາດ, ທີ່ມີຕະກອນຫລາຍແລະເປັນນ້ໍາຂະຫນາດໃຫຍ່ທີ່ຂ້ອນຂ້າງຍັງອາດຂຶ້ນອ່າງເກັບນ. ເພາະສະນັ້ນ, ໃນຂະນະທີ່ການນໍາໃຊ້ອ່າງເກັບນມັນເປັນການຮັບຮອງເອົາວິທີການຂອງການປິດລະບົບຊົ່ວຄາວສໍາລັບການ desilting ອີງຕາມການຕົກຕະກອນຂາເຂົ້າຂອງນ້ໍາ, ສະນັ້ນທີ່ຈະເປັນການຫຼີກເວັ້ນການ SILTE ຕະກອນທີ່ມີຜົນຕໍ່ການໄດ້ຮັບປົກກະຕິຂອງ HPP ໄດ້.
ສະເລ່ຍແຂວນຫລາຍປີມາອ່າງເກັບນຂອງ Hoauy Por HPP ໄດ້ ເປັນ 104,000t, ແລະເນື້ອໃນຂອງສະເລ່ຍຂອງພືດຕະກອນເປັນ 199g / m3; ໂດຍສະເລ່ຍຂອງຕະກອນແຂວນລອຍເຂົ້າມາໃນອ່າງເກັບນໃນໄລຍະລະດູການນ້ໍາຂອງເດືອນພຶດສະພາຫາເດືອນຕຸລາແມ່ນ 91,100t, ເນື້ອໃນຂອງຕະກອນໂດຍສະເລ່ຍແມ່ນ 427.45 g / m3, ແລະຕະກອນໃນໄລຍະການບັນຊີທີ່ລະດູການນ້ໍາສໍາລັບການ 875%. ນັບຕັ້ງແຕ່ອັດຕາການ SILTE ຕະກອນຂອງເຂດພື້ນທີ່ອ່າງເກັບນເປັນຄ່ອນຂ້າງໄວ, thesediment ບັນຫາການຄວບຄຸມຂອງ headrace ຂອງສະລັບສັບຊ້ອນ Headwork ຂອງ HPP ແມ່ນເປັນຄູຊັດເຈນທີ່ຂ້ອນຂ້າງ. ເພື່ອປ້ອງກັນການຕົກຕະກອນຈາກການເຂົ້າມາບໍລິໂພກນ້ໍາ, ການຮັກສາຄວາມສາມາດໃນການເກັບຮັກສາຂອງ HPP ແມ່ນວຽກງານຕົ້ນຕໍສໍາລັບການອອກແບບຕະກອນໃນໂຄງການນີ້. ວິທີຫ້ວຍ Por HPP ອາດຈະຫຼຸດຜ່ອນການຂັດຖູຂອງ turbine ໂດຍຜ່ານຕະກອນໄດ້, ດັ່ງນັ້ນທີ່ຈະເປັນການຮັບປະກັນການດໍາເນີນງານຄວາມປອດໄພຂອງ HPP ໄດ້, ແມ່ນຍັງເປັນບັນຫາຕະກອນວິສະວະກໍາທີ່ຈະໄດ້ຮັບການແກ້ໄຂ.
ອີງຕາມການວິເຄາະຂໍ້ມູນຂອງຕະກອນປະລິມານຂອງຕະກອນໃນແມ່ນສຸມຕົ້ນຕໍໃນການສູງສຸດບໍ່ຫຼາຍປານໃດ ນ້ໍາຖ້ວມ. ຕາມສະຖິຕິຂອງຂໍ້ມູນທີ່ໄຫລຈໍານວນສະເລ່ຍຂອງມື້ທີ່ມີການສະເລ່ຍປະຈໍາວັນອອກໂຮງຫມໍຂະຫນາດໃຫຍ່ກ່ວາ 350m3 / s ແມ່ນ 3 ວັນແລະອັດຕາສ່ວນຂອງ quatity ຕະກອນຂະຫນາດໃຫຍ່ທີ່ຂ້ອນຂ້າງ. ເພາະສະນັ້ນ, ມັນແມ່ນການເລືອກເອົາການລົງຂາວນ້ໍາຖ້ວມສູງສຸດເປັນ 350m3 / s ປະຕູຮົ້ວຂອງ HPP ແມ່ນມີການເປີດເຜີຍຢ່າງເຕັມສ່ວນແລະມັນເປັນທີ່ຈະປິດລົງສໍາລັບ desilting.
ມັນເປັນການຮັບຮອງເອົາວິທີການ gradient equilibrium ເພື່ອປະເມີນ SILTE ຕະກອນຂອງອ່າງເກັບໃນພື້ນທີ່ຂອງບ້ານຫ້ວຍ Por HPP.
ໃນການຄິດໄລ່ desilting ຂອງຕະກອນອ່າງເກັບມັນເປັນການຮັບຮອງເອົາຫນຶ່ງໃນວິທີຄິດໄລ່ໄດ້ແລະຕົວແບບຄະນິດສາດແນະນໍາຢູ່ໃນສະເພາະສໍາລັບການອອກແບບຕະກອນຂອງພະລັງງານແລະນ້ໍາທີ່ອະນຸລັກໂຄງການຕົວແບບຄະນິດສາດຂອງຕະກອນ SUJSBED-II ການນ້ໍາພັດທະນາໂດຍ Wuhan ວິທະຍາ.
SILTE ຕະການທີ່ ຂອງເຂດພື້ນທີ່ອ່າງເກັບນຂອງ HPP ໄດ້ຖືກທີ່ກ່ຽວຂ້ອງກັບການໄຫຼເຂົ້າ U / S ນ້ໍາແລະການຕົກຕະກອນມາ, ເຊັ່ນດຽວກັນກັບພູມິປະເທດຂອງອ່າງເກັບນແລະການດໍາເນີນຄວາມຫມາຍຂອງ HPP. ອີງຕາມການປະຕິບັດງານອ່າງເກັບນຫມາຍເຖິງການສະເຫນີກ່ອນທີ່ຈະ, ມັນແມ່ນການຮັບຮອງເອົາຮູບແບບທີ່ຄະນິດສາດຂອງຕະກອນນ້ໍາ USBED-II ທີ່ຈະຄິດໄລ່ຂະບວນການ desilting ການຕົກຕະກອນ, ການຄິດໄລ່ຜົນໄດ້ຊີ້ໃຫ້ເຫັນວ່າ: ຈໍານວນຂອງປີ equilibrium ຕະກອນຈະເປັນ 50 ປີ, ຕະກອນຕົກຕະກອນໃນ ອ່າງເກັບນຈະ 27,000m3, ແລະຄວາມສາມາດໃນການເກັບຮັກສາຍັງເຫຼືອຕ່ໍາກວ່າ FSL ເປັນ 49,000m3.

Being translated, please wait..

Results (Lao) 2:[Copy]

Copied!

Being translated, please wait..

Results (Lao) 3:[Copy]

Copied!

Being translated, please wait..

Other languages

The translation tool support: Afrikaans, Albanian, Amharic, Arabic, Armenian, Azerbaijani, Basque, Belarusian, Bengali, Bosnian, Bulgarian, Catalan, Cebuano, Chichewa, Chinese, Chinese Traditional, Corsican, Croatian, Czech, Danish, Detect language, Dutch, English, Esperanto, Estonian, Filipino, Finnish, French, Frisian, Galician, Georgian, German, Greek, Gujarati, Haitian Creole, Hausa, Hawaiian, Hebrew, Hindi, Hmong, Hungarian, Icelandic, Igbo, Indonesian, Irish, Italian, Japanese, Javanese, Kannada, Kazakh, Khmer, Kinyarwanda, Klingon, Korean, Kurdish (Kurmanji), Kyrgyz, Lao, Latin, Latvian, Lithuanian, Luxembourgish, Macedonian, Malagasy, Malay, Malayalam, Maltese, Maori, Marathi, Mongolian, Myanmar (Burmese), Nepali, Norwegian, Odia (Oriya), Pashto, Persian, Polish, Portuguese, Punjabi, Romanian, Russian, Samoan, Scots Gaelic, Serbian, Sesotho, Shona, Sindhi, Sinhala, Slovak, Slovenian, Somali, Spanish, Sundanese, Swahili, Swedish, Tajik, Tamil, Tatar, Telugu, Thai, Turkish, Turkmen, Ukrainian, Urdu, Uyghur, Uzbek, Vietnamese, Welsh, Xhosa, Yiddish, Yoruba, Zulu, Language translation.