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[표제지 등]=0,1,2

제출문=1,3,1

요약문=2,4,4

Summary=6,8,4

Contents=10,12,1

목차=11,13,1

표차례=12,14,5

그림차례=17,19,13

제1장 연구개발과제의 개요=30,32,5

제2장 국내외 기술개발 현황=35,37,1

제1절 시스템 구성=35,37,2

제2절 가대구조=36,38,3

제3절 베드 구조=38,40,2

제4절 급액 배액 관리=40,42,1

제5절 배지온 관리=40,42,2

제3장 딸기의 고설수경재배 신기술 체계 확립=42,44,1

제1절 딸기 고설수경재배용 적정배지 개발=42,44,30

제2절 배양액 관리기술 개발=72,74,50

제3절 근권 활력 증대 기술 개발=122,124,33

제4장 딸기 고설수경 재배 시스템 개발=155,157,1

제1절 구조해석=155,157,6

제2절 작업성=160,162,3

제3절 배액 재이용 시스템 구성=163,165,13

제4절 배지온 관리 시스템=176,178,37

제5절 현장 적응시험 및 경제성 분석=213,215,9

제5장 목표달성도 및 관련분야에의 기여도=222,224,1

제6장 연구개발결과의 활용계획=223,225,1

제7장 연구개발과정에서 수집한 해외과학기술정보=224,226,1

제8장 참고문헌=225,227,11

표차례

Table 1-1. 1차 년도(2002.10. ~ 2003. 10.)=33,35,1

Table 1-2. 2차 년도(2003. 10. ~ 2004. 10.)=33,35,1

Table 1-3. 3차 년도(2004. 10. ~ 2005. 10.)=34,36,1

Table 3-1. Effect Of Substrate On Early Growth Of Strawberries In Hydroponics In Greenhouse=44,46,1

Table 3-2. Effect Of Substrate On Fruit Quality And Yield Of Strawberries In Hydroponics In Greenhouse=45,47,1

Table 3-3. Effect Of Substrate On Total Yield And Fruit Quality In Hydroponics=46,48,1

Table 3-4. Effect Of Substrate On Total Growth Of Strawberries In Hydroponics In Greenhouse=47,49,1

Table 3-5. Effect Of Substrate On Early Stage Growth Of Strawberries In Hydroponics In Plastic House=48,50,1

Table 3-6. Effect Of Substrate On The Late Growth Stage Of Strawberry Hydroponics In Plastic House=49,51,1

Table 3-7. Effect Of Substrate On The Late Growth Stage Of Strawberry Hydroponics In Plastic House=49,51,1

Table 3-8. Yamazaki'S Nutrient Solution Composition For Strawberry=52,54,1

Table 3-9. Experiment Dairy In Glasshouse=53,55,1

Table 3-10. Effect Of Substrate On Early Growth Of Strawberries In Hydroponics In Plastic House=55,57,1

Table 3-11. Effect Of Substrate On Fruit Quality And Yield Of Strawberries N Hydroponics In Plastic House=56,58,1

Table 3-12. Effect Of Substrate On Total Yield And Fruit Quality In Hydroponics In Plastic House=58,60,1

Table 3-13. Effect Of Bed Shape On Early Growth Of Strawberries In Different Growth Substrates In Plastic House=60,62,1

Table 3-14. Effect Of Bed Shape On Fruit Quality And Yield Of Strawberries In Different Growth Substrates In Plastic House=61,63,1

Table 3-15. Effect Of Subsirate On Early Growth Of Strawberries In Hydroponics In Plastic House=65,67,1

Table 3-16. Effect Of Substrate On Fruit Quality And Yield Of Strawberries In Hydroponics In Plastic House=66,68,1

Tabie 3-17. Effect Of Substrate On Total Yield And Fruit Quality In Hydroponics In Plastic House=67,69,1

Table 3-18. Effect Of Perlite Substrate Volume Per Plant On Early Growth Of Strawberries At Different Growth Stage In Hydroponics In Glasshouse=69,71,1

Table 3-19. Effect Of Perlite Substrate Volume Per Plant On Fruit Quality And Yield Of Strawberries At Different Growth Stage In Hydroponics In Glasshouse=70,72,1

Table 3-20. Effect Of Perlite Substrate Volume Per Plant On Total Yield And Fruit Quality In Hydroponics In Glasshouse=71,73,1

Table 3-21. Yamazaki'S Nutrient Solution Composition For Strawberry=73,75,1

Table 3-22. Yamazaki'S Nutrient Solution Composition For Strawberry=84,86,1

Table 3-23. Nutrient Solution Composition By Chiba Prefectural Agriculture Research Center For Strawberry=85,87,1

Table 3-24. Nutrient Solution Composition By PBG In Netherlands=86,88,1

Table 3-25. Effect Of Nutrient Solution Composition On Early Growth Of Strawberries In Hydroponics In Greenhouse=90,92,1

Table 3-26. Effect Of Nutrient Solution Composition On Fruit Quality And Yield Of Strawberries In Hydroponics In Greenhouse=91,93,1

Table 3-27. Effect Of Nutrient Solution Composition On Total Yield And Fruit Quality In Hydroponics In Greenhouse=92,94,1

Table 3-28. Effect Of The Amount Of Nutrient Solution Supplied Per Plant A Day On Early Growth Of Strawberries In Two Litter Perlite Substrate In Glasshouse=111,113,1

Table 3-29. Effect Of The Amount Of Nutrient Solution Supply Per Plant A Day On Total Yield And Fruit Quality In Perlite Substrate Culture In Glasshouse=112,114,1

Table 3-30. Effect Of Microbes On Fruit Quality And Yield Of Strawberries In Cocopeat Substrates In Plastic House=124,126,1

Table 3-31. Effects Of Microbes On Fruit Quality And Yield Of Strawberries In Vermiculite And Rice Hull Substrate In Plastic House=125,127,1

Table 3-32. Effect Of Physiologically Active Substances On Fruit Quality And Yield Of Strawberries In Perlite Substrate In Glasshouse=129,131,1

Table 3-33. Effect Of Physiologically Active Substance On Fruit Quality And Yield Of Strawberry=130,132,1

Table 3-34. Effect Of Root Zone Temperature On Early Growth Of Strawberry In Hydroponics=142,144,1

Table 3-35. Effect Of Root Zone Temperature On Fruit Quality And Yield Of Strawberry In Hydroponics=143,145,1

Table 3-36. Effect Of Circulating Nutrient Solution Temperature On Growth Of Strawberry In NFT System=147,149,1

Table 3-37. Effect Of Circulating Nutrient Solution Temperature On Partly Growth Of Strawberry In NFT System=148,150,1

Table 3-38. Effect Of Bed Shape On Early Growth Of Strawberries In Different Growth Substrates In Plastic House=152,154,1

Table 3-39. Effect Of Bed Shape On Fruit Quality And Yield Of Strawberries In Different Growth Substrates In Plastic House=153,155,1

표 4-1. 베드별 1m당 재료 중량=157,159,1

표 4-2. 가대 지주의 안전성=158,160,1

표 4-3. 가대 가로대 하중 안전성=158,160,1

표 4-4. 가대 가로대 처짐 안전성=160,162,1

표 4-5. 작업별 노동투하시간 (hr/10a)=161,163,1

표 4-6. 주요 작업성 시험 결괴=162,164,1

표 4-7. 타이머 방식 배액율 제어 성능=174,176,1

표 4-8. 급액ㆍ배액 탱크 수위차 비교방식 배액율 제어 성능=174,176,1

표 4-9. 딸기 고설수경재배와 토경의 생산량 및 소득 비교=218,220,1

표 4-10. 딸기 고설수경재배 시스템의 경제성 분석=220,222,1

그림차례

Fig. 3-1. Changes Of Air Temperature And Humidity During The Experiment In Plastic House(Every 1Hours)=53,55,1

Fig. 3-2. Changes In Absorption Concentration Of NO₃-N Of Strawberries In Four Different Hydroponic Substrates=75,77,1

Fig. 3-3. Changes In Absorption Concentration Of P Of Strawberries In Four Different Hydroponic Substrates=75,77,1

Fig. 3-4. Change In Absorption Concentration Of K Of Strawberries In Four Different Hydroponic Substrates=76,78,1

Fig. 3-5. Change In Absorption Concentration Of Ca Of Strawberries In Four Different Hydroponic Substrates=76,78,1

Fig. 3-6. Changes In Absorption Concentration Of Mg Of Strawberries In Four Different Hydroponic Substrates=77,79,1

Fig. 3-7. Changes In Absorption Concentration Of Fe Of Strawberries In Four Different Hydroponic Substrates=77,79,1

Fig. 3-8. Change In Absorption Concentration Of B Of Strawberries In Four Different Hydroponic Substrates=78,80,1

Fig. 3-9. Changes In Absorption Concentration Of Mn Of Strawberries In Four Different Hydroponic Substrates=78,80,1

Fig. 3-10. Changes In Absorption Concentration Of Zn Of Strawberries In Four Different Hydroponic Substrates=79,81,1

Fig. 3-11. Changes In Absorption Concentration Of Cu Of Strawberries In Four Different Hydroponic Substrates=79,81,1

Fig. 3-12. Changes Of Absorption Concentration Of NO₃-N Of Strawberries In Recirculated Nutrient Solution In Glasshouse=81,83,1

Fig. 3-13. Changes Of Absorption Concentration Of PO₄-P Strawberries In Recirculated Nutrient Solution In Glasshouse=82,84,1

Fig. 3-14. Changes Of Absorption Concentration Of K Of Strawberries In Recirculated Nutrient Solution In Glasshouse=82,84,1

Fig. 3-15. Changes Of Absorption Concentration Of Ca Of Strawberries In Recirculated Nutrient Solution In Glasshouse=83,85,1

Fig. 3-16. Changes Of Absorption Concentration Of Mg Of Strawberries In Recirculated Nutrient Solution In Glasshouse=83,85,1

Fig, 3-17. Changes In Absorption Concentration Of NO₃-N Of Strawberries With Three Different Nutrient Solution Compositions In Cocopeat Substrate=87,89,1

Fig. 3-18. Changes In Absorption Concentration Of P Of Strawberries With Three Different Nutrient Solution Compositions In Cocopeat Substrate=87,89,1

Fig. 3-19. Changes In Absorption Concentration Of K Of Strawberries With Three Different Nutrient Solution Compositions In Cocopeat Substrate=88,90,1

Fig. 3-20. Changes In Absorption Concentration Of Ca Of Strawberries With Three Different Nutrient Solution Compositions In Cocopeat Substrate=88,90,1

Fig. 3-21. Changes In Absorption Concentration Of Mg Of Strawberries With Three Different Nutrient Solution Compositions In Cocopeat Substrate=89,91,1

Fig. 3-22. Changes Of EC Of Recirculated Nutrient Solution In Four Different Hydroponic Substrates=94,96,1

Fig. 3-23. Changes Of EC Of Recirculated Nutrient Solution In Different Substrate Volumes During The Experiment In Glasshouse=94,96,1

Fig. 3-24. Changes Of EC Of Recirculated Nutrient Solution As Different Amount Of Solution Supplied In Two Litter Perlite Substrate During The Experiment In Glasshouse=95,97,1

Fig. 3-25. Changes Of EC Of Recirculated Nutrient Solution With Different Solution Of Composition Supplied In Two Litter Perlite Substrate During The Experiment In Glasshouse=96,98,1

Fig. 3-26. Changes Of EC Of Recirculated Nutrient Solution In Different Substrates During The Experiment In Plastic House=96,98,1

Fig. 3-27. Changes Of EC Of Recirculated Nutrient Solution In Different Substrates During The Experiment In Plastic House=97,99,1

Fig. 3-28. Changes In pH Of Circulated Nutrient Solution In Four Different Hydroponic Substrates=99,101,1

Fig. 3-29. Changes Of pH Of Recirculated Nutrient Solution In Different Substrate Volumes During The Experiment In Glasshouse=100,102,1

Fig. 3-30. Changes Of pH Of Recirculated Nutrient Solution As Amount Of Solution Supplied In Two Litter Perlite Substrate During The Experiment In Glasshouse=100,102,1

Fig. 3-31. Changes Of pH Of Recirculated Nutrient Solution With Different Solution Of Composition Supplied In Two Litter Perlite Substrate During The Experiment In Glasshouse=101,103,1

Fig. 3-32. Changes Of pH Of Recirculated Nutrient Solution In Different Substrates During The Experiment In Plastic House=102,104,1

Fig. 3-33. Changes Of pH Of Recirculated Nutrient Solution In Different Substrate During The Experiment In Plastic House=103,105,1

Fig. 3-34. Changes In Moisture Contents In Different Substrates In Greenhouse Durin The Experiment=105,107,1

Fig. 3-35. Changes Of Nutrient Solution Absorption Amount In Four Different Substrates During The Experiment=106,108,1

Fig. 3-36. Changes Of Water Contents In Perlite Substrates As Different Substrate Volumes During The Experiment In Glasshouse=106,108,1

Fig. 3-37. Changes Of Water Contents In Two Litter Perlite Substrate As Different Amount Of Solution Supplied During The Experiment In Glasshouse=107,109,1

Fig. 3-38. Changes Of EC And Amounts Of Nutrient Solution Absorption Per Plant A Day In Two Litter Perlite Substrate With 250ml Solution Supplied Durin The Experiment In Glasshouse=108,110,1

Fig. 3-39. Changes Of Nutrient Solution Absorption Per Plant A Day In Three Different Nutrient Solution Compound During The Experiment In Glasshouse=108,110,1

Fig. 3-40. Changes Of Water Contents In Different Substrates In Bio-Bed During The Experiment In Plastic House=109,111,1

Fig. 3-41. Changes Of Water Contents In Different Substrates In Normal Bed During The Experiment In Plastic House=109,111,1

Fig. 3-42. Changes Of Water Contents In Perlite And Cocopeat Substrates In Bio-Bed And Normal Bed During The Experiment In Plastic House=110,112,1

Fig. 3-43. Changes Of NO₃-N Concentration In Recirculated Nutrient Solution In Cocopeat And Perlite Substrates During The Experiment In Plastic House=115,117,1

Fig. 3-44. Changes Of P Concentration In Recirculated Nutrient Solution In Cocopeat And Perlite Substrates During The Experiment In Plastic House=115,117,1

Fig. 3-45. Changes Of K Concentration In Recirculated Nutrient Solution In Cocopeat And Perlite Substrates During The Experiment In Plastic House=116,118,1

Fig. 3-46. Changes Of Ca Concentration In Recirculated Nutrient Solution In Cocopeat And Perlite Substrates During The Experiment In Plastic House=116,118,1

Fig. 3-47. Changes Of Mg Concentration In Recirculated Nutrient Solution In Cocopeat And Perlite Substrates During The Experiment In Plastic House=117,119,1

Fig. 3-48. Changes Of NO₃-N Concentration In Recirculated Nutrient Solution In Three Different Substrates During The Experiment In Plastic House=118,120,1

Fig. 3-49. Changes Of P Concentration In Recirculated Nutrient Solution In Three Different Substrates During The Experiment In Plastic House=118,120,1

Fig. 3-50. Changes Of K Concentration In Recirculated Nutrient Solution In Three Different Substrates During The Experiment In Plastic House=119,121,1

Fig. 3-51. Changes Of Ca Concentration In Recirculated Nutrient Solution In Three Different Substrates During The Experiment In Plastic House=119,121,1

Fig. 3-52. Changes Of Mg Concentration In Recirculated Nutrient Solution In Three Different Substrates During The Experiment In Plastic House=120,122,1

Fig. 3-53. Effect Of Microbes On Changes Of Strawberry Leaves In Cocopeat Substrate In Plastic House=126,128,1

Fig. 3-54. Effect Of Microbes On Changes Of Strawberry Leaves In Vermiculite And Rice Hull Substrate In Plastic House=126,128,1

Fig. 3-55. Effect Of Physiologically Active Substances On Strawberry Leaves In Perlite Substrate In Glasshouse=130,132,1

Fig. 3-56. Changes In Maximum And Minimum Root Zone Temperature Of Four Different Hydroponic Substrates In Greenhouse=132,134,1

Fig. 3-57. Changes In Max. And Min. Root Zone Temperature Of Two Hydroponic Substrates In Plastic House=133,135,1

Fig. 3-58. Changes In Mean Temperature Of Circulated Nutrient Solution In Plastic House=134,136,1

Fig. 3-59. Changes Of Maximum Temperature In Different Substrates During The Experiment In Plastic House=134,136,1

Fig. 3-60. Changes Of Minimum Temperature In Different Substrates During The Experiment In Plastic House=135,137,1

Fig. 3-61. Changes Of Maximum And Minimum Temperature In Substrate As Different Substrate Volume During The Experiment In Glasshouse=135,137,1

Fig. 3-62/61. Changes Of Nutrient Solution Temperature In Tank On And Under Round Durin The Experiment In Plastic House=136,138,1

Fig. 3-63. 비닐하우스 배지종류별 근권부 온도의 변화 추이=137,139,1

Fig. 3-64. 비닐하우스 배지종류별 순환배양액의 온도 변화 추이=137,139,1

Fig. 3-65. 배지가온실험 무가온 처리구의 배지 내 위치별 온도변화 추이=140,142,1

Fig. 3-66. 배지가온실험 13℃ 처리구의 배지 내 위치별 온도변화 추이=140,142,1

Fig. 3-67. 배지가온실험 18℃ 처리구의 배지 내 위치별 온도변화 추이=141,143,1

Fig. 3-68. 딸기 NFT 재배시스템 근온 처리의 배양액 온도변화 추이=146,148,1

Fig. 3-69. 딸기수경재배 NFT 근온 실험 온실의 온도 습도 변화추이=146,148,1

그림 4-1. 베드의 구조=155,157,1

그림 4-2. 지주 높이별 가대 구조=156,158,1

그림 4-3. 베드 및 가대의 침하방지 구조=157,159,1

그림 4-4. 배액의 재이용 개념도=163,165,1

그림 4-5. 배액율 제어 시스템 구성=164,166,1

그림 4-6. 배액율 제어 시스템=165,167,1

그림 4-7. 배액율 제어 시스템 회로도=166,168,1

그림 4-8. 타이머 방식 배액율 제어 흐름도=167,169,1

그림 4-9. 급액ㆍ배액 탱크 수위차 비교방식 배액율 제어 흐름도=169,171,1

그림 4-10. 급액유량 컴퓨터 USB 인터페이스=170,172,1

그림 4-11. 펌프가동시간에 따른 급액량=171,173,1

그림 4-12. 펌프가동시간에 따른 배액량=172,174,1

그림 4-13. 펌프가동시간에 따른 배액율=172,174,1

그림 4-14. 생육스테이지에 따른 필요 관수량=173,175,1

그림 4-15. 배액율제어 방식별 제어성능 비교=175,177,1

그림 4-16. 온실내 온도변화에 따른 배지온 변화 시험장치 구성도=177,179,1

그림 4-17. 온실내 온도변화에 따른 배지온 변화 시험장치=178,180,1

그림 4-18. 냉방기=178,180,1

그림 4-19. 쳄버 내 온도 조절 장치=179,181,1

그림 4-20. 온도변화 측정 데이터 로그 장치(Hewlett Packard)=179,181,1

그림 4-21. 시험에 사용한 베드의 구조=180,182,1

그림 4-22. 온도센서 설치 위치=181,183,1

그림 4-23. 멀칭 유무=182,184,1

그림 4-24. 온도 측정 센서 설치 방법=182,184,1

그림 4-25. 플랜트형 베드의 배지별 배지온 강하(실내온도 1.5℃)=185,187,1

그림 4-26. 플랜트형 베드의 배지별 배지온 강하(실내온도 3.2℃)=186,188,1

그림 4-27. 플랜트형 베드의 배지별 배지온 강하(실내온도 5℃)=187,189,1

그림 4-28. 플랜트형 베드의 배지별 배지온 강하(실내온도 6.7℃)=188,190,1

그림 4-29. V형 베드에서 온실내 온도1.5도 때 배지내 온도강하 특성=189,191,1

그림 4-30. V형 베드에서 온실내 온도3.2도 때 배지내 온도강하 특성=190,192,1

그림 4-31. V형 베드에서 온실내 온도 5도 때 배지내 은도강하 특성=191,193,1

그림 4-32. V형 베드에서 온실내 온도6.7도 때 배지내 온도강하 특성=192,194,1

그림 4-33. 베드별 온도분포(펄라이트+ 피트, 무멸칭)=193,195,1

그림 4-34. 단독배지의 배지별 배지내 온도분포=194,196,1

그림 4-35. 혼합배지의 배지별 배지내 온도분포=195,197,1

그림 4-36. 멀칭 유무별 온도분포=196,198,1

그림 4-37. 플랜트형 베드의 배지온과 온실내 기온차에 따른 온도강하율=197,199,1

그림 4-38. V형 베드에서 배지온과 온실내 기온차에 따른 온도강하율=198,200,1

그림 4-39. 베드별 지하수 파이프 설치 위치=199,201,1

그림 4-40. 지하수 공급 유량 인디케이터=199,201,1

그림 4-41. 실내온도 1.5℃일 때 지하수에 의한 배지온 상승=200,202,1

그림 4-42. 실내온도 3.2℃일 때 지하수에 의한 배지온 상승=201,203,1

그림 4-43. 실내온도 5℃일 때 지하수에 의한 배지온 상승=203,205,1

그림 4-44. 실내온도 6.7℃일 때 지하수에 의한 배지온 상승=204,206,1

그림 4-45. 지하수에 의한 배지 가온시 배지별 배지온 분포=205,207,1

그림 4-46. 고설재배 시스템=206,208,1