• Asian-Australasian Journal of Animal Sciences
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• 제26권3호
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• pp.433-442
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• 2013

This study aimed to compare the dynamics of air temperature and velocity under two different ventilation and housing systems during summer and winter in Korea. The $NH_3$ concentration of both housing systems was also investigated in relation to the pig's growth. The ventilation systems used were; negative pressure type for the enclosed pig house (EPH) and natural airflow for the conventional pig house (CPH). Against a highly fluctuating outdoor temperature, the EPH was able to maintain a stable temperature at 24.8 to $29.1^{\circ}C$ during summer and 17.9 to $23.1^{\circ}C$ during winter whilst the CPH had a wider temperature variance during summer at 24.7 to $32.3^{\circ}C$. However, the temperature fluctuation of the CPH during winter was almost the same with that of EPH at 14.5 to $18.2^{\circ}C$. The NH3 levels in the CPH ranged from 9.31 to 16.9 mg/L during summer and 5.1 to 19.7 mg/L during winter whilst that of the EPH pig house was 7.9 to 16.1 mg/L and 3.7 to 9.6 mg/L during summer and winter, respectively. These values were less than the critical ammonia level for pigs with the EPH maintaining a lower level than the CPH in both winter and summer. The air velocity at pig nose level in the EPH during summer was 0.23 m/s, enough to provide comfort because of the unique design of the inlet feature. However, no air movement was observed in almost all the lower portions of the CPH during winter because of the absence of an inlet feature. There was a significant improvement in weight gain and feed intake of pigs reared in the EPH compared to the CPH (p<0.05). These findings proved that despite the difference in the housing systems, a stable indoor temperature was necessary to minimize the impact of an avoidable and highly fluctuating outdoor temperature. The EPH consistently maintained an effective indoor airspeed irrespective of season; however the CPH had defective and stagnant air at pig nose level during winter. Characteristics of airflow direction and pattern were consistent relative to housing system during both summer and winter but not of airspeed. The ideal air velocity measurement favored the EPH and therefore can be appropriate for the Korean environment. Further emphasis on its cost effectiveness will be the subject of future investigations.

• Asian-Australasian Journal of Animal Sciences
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• 제32권5호
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• pp.742-747
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• 2019

Objective: A concentration of airborne bacteria generated from swine houses is recognized to be relatively higher than other work places and it is essential to optimally manage it to prevent farmers' respiratory diseases. This study was conducted to assess the distribution characteristics of airborne bacteria in swine houses located at South Korea. Methods: A total 27 pig buildings of the enclosed type operated with mechanical ventilation system by a side wall fan and deep-pit manure system with slats were surveyed. Air samples were collected at 1.0 m above the middle floor in pig housing room. A six-stage viable particulate cascade impactor was used to identify the distribution of the sizes of particles in diameter. Results: Seasonal mean levels of airborne bacteria in the housing rooms of gestation/farrowing pigs, nursery pigs and growing/fattening pigs were 3,428(${\pm}1,244$) colony forming unit $(cfu)/m^3$, $8,325({\pm}3,209)cfu/m$, and $13,254({\pm}6,108)cfu/m^3$ for spring; $9,824({\pm}2,157)cfu/m^3$, $18,254({\pm}5,166)cfu/m^3$, and $24,088({\pm}9,274)cfu/m^3$ for summer; $1,707({\pm}957)cfu/m^3$, $4,258({\pm}1,438)cfu/m^3$, and $8,254({\pm}2,416)cfu/m^3$ for autumn; and $2,322({\pm}1,352)cfu/m^3$, $6,124({\pm}1,527)cfu/m^3$ and $12,470({\pm}4,869)cfu/m^3$ for winter, respectively. Conclusion: Concentrations of airborne bacteria according to pig housing type were highest in growing/fattening housing room followed by nursery housing room and gestation/farrowing housing room. In terms of seasonal aspect, the pig building showed the highest levels of airborne bacteria in summer followed by spring, winter and autumn. The respirable airborne bacteria which are ranged between 0.6 and $4.7{\mu}m$ accounted for approximately 60% compared to total airborne bacteria regardless of pig housing type.

• Journal of Animal Science and Technology
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• 제44권1호
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• pp.135-144
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• 2002

본 실험은 우리 나라의 양돈농가에서 노동력 절감이라는 이점 때문에 자돈사 및 분만사의 무창돈사는 일반농가에까지 보급되고 있으나, 육성.비육돈사에 있어서 무창돈사는 거의 전무한 실정으로 질병의 근원적인 차단 및 관리를 위하여 지금까지 회피되어 왔던 무창 육성.비육돈사의 활성화를 위하여 환기시스템을 자체적으로 고안하여 최적의 환기시스템을 여름철 및 겨울철로 구분하여 건축하였으며, 자체적으로 고안한 환기시스템의 성능을 평가하고자 겨울철 및 여름철로 구분하여 시험한 결과를 요약하면 다음과 같다. 1. 무창 육성.비육돈사에 있어서 돼지 생활공간(하부) 지점에서의 공기유속은 겨울철 최소환기 수준(1,440 $m^3/h$)으로 하였을 때 0-0.19 m/s 였으며, 여름철 최대환기 수준(24,000 $m^3/h$)에서는 0.07-0.42 m/s로 분포되어 여름철 및 겨울철의 무창돈사내 공기유속으로 보아 환기시스템이 우수하였다. 이상의 실험결과를 종합해 보면 무창 육성.비육사의 환기시스템은 여럼츨 때는 측벽을 통한 환기와 겨울철은 천장을 통한 환기시스템이 적합하다고 판단되었으며, 한쪽 측벽에 의한 배기시스템이라도 입기구는 양쪽 측벽을 통한 입기가 우수하다는 것을 알 수 있었다.

• 한국축산시설환경학회지
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• 제11권1호
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• pp.45-54
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• 2005

본 연구는 대규모, 중규모, 소규모 양돈장을 선정 각 성장단계별 돈사내 및 부지경계선에서 악취물질 발생 농도에 대한 1차적인 기초 자료를 얻고자 수행하였다. 조사한 돈사의 형태는 무창돈사, 개방돈사이며 분뇨처리는 슬러리, 톱밥돈사 등으로 구성되어 있었다. 돈사 내에서 악취물질 발생 농도를 조사한 결과 성장단계, 사육규모에 관계없이 암모니아:0.9${\~}$21.0ppm으로 가장 높았고, 그 다음 황화수소:51.9${\~}$6,712.4ppb, 메틸머캅탄:N. D.${\~}$12.9ppb, 다이메틸설파이드:N. D.${\~}$5.2ppb, 다이메틸다이설 파이드:N. D.${\~}$2.6ppb 순으로 악취물질 발생 농도가 낮은 것으로 나타났다. 부지경계의 악취물질 농도는 돈사시설에서 풍하 방향을 고려하여 20m 외곽에서 실시하였다. 조사 당시 풍속은 0.23${\~}$0.73m/s 이었다. 악취물질 발생 농도 범위는 암모니아 0.2${\~}$4.5ppm, 황화수소 0.0l${\~}$0.06ppb, 메틸머캅탄 N. D.${\~}$0.009ppb, 다이메틸다이설파이드 N. D.${\~}$0.002ppb가 측정되었다. 악취물질별로 돈사 내 및 부지경계 기준악취물질 발생농도를 비교한 결과 악취물질 발생농도는 다이메틸설파이드 가장 낮게 검출되었으며 그 다음 황화수소, 암모니아, 메틸머캅탄, 다이메틸다이설파이드 순으로 검출되었다. 금후 돈사 내 악취물질 발생 및 그 원인에 대하여는 돈사 내$\cdot$외 환경 여건 변화에 따라 다양하므로 좀더 많은 연구가 필요한 것으로 판단된다.