Methods for evaluation of the thermal environment in the animal occupied zone for weaned piglets

Two evaluation methods are introduced for expression of the quality of the thermal conditions in the animal-occupied zone (AOZ) in rooms for weaned piglets. One method uses only the AOZ temperature, while the other uses the kata-value (KV), which combines air velocity and temperature and indicates the heat loss to the environment. AOZ thermal conditions should be within the thermo-neutral zone (TNZ) of the piglets. The methods use two new numerical indicators, based on the duration and the magnitude of excess of AOZ thermal conditions outside the TNZ: one referring to the number of degree-hours (°Ch), and the other to the number of kata-value-hours (KVh) during a batch. The objective was to evaluate the two methods in a door-ventilated room for weaned piglets. In the experiment, temperature was measured in all ten pens of a room and air velocity in three pens during eight successive batches, together lasting about one year. Pens closer to the air inlet had higher temperatures and lower KV than pens in the back of the room. Momentary temperature difference between pens reached up to 7°C. During the first days of most batches, pen conditions in the back of the room were “too cold.” At the end of most batches, pen conditions in the middle of the room were “too warm.” The value of the two indicators varied per pen and per batch from 0 to 319°Ch (0 to 219 KVh) “too cold” and from 0 to 602°Ch (0 to 793 KVh) “too warm.” For “too warm” conditions, there was a significant (P 0.96), but not for “too cold” conditions (R2 > 0.48). Therefore, measuring air velocity in addition to temperature in the AOZ for recognition of “too cold” conditions had surplus value. Excluding outliers from one extremely warm batch, the maximum value of the indicator for “too warm” was 65°Ch. This indicator significantly affected the feed conversion ratio, which increased with 0.0024 kg/kg per °Ch, and daily growth and daily feed intake, which decreased with 0.0022 kg/animal and 0.0030 kg/animal, respectively, per °Ch. The methods presented are useful tools in the technical evaluation of climate systems and for a more optimal climate control in the AOZ.

[1]  A. V. van Wagenberg,et al.  CONTAMINANT AND HEAT REMOVAL EFFECTIVENESS OF THREE VENTILATION SYSTEMS IN NURSERY ROOMS FOR PIGS , 2002 .

[2]  S. Hoff Isothermal Airflow Characteristics in the Animal-occupied Zone of a Slot-ventilated Swine Facility , 1995 .

[3]  Petros Axaopoulos,et al.  COMPARISON OF TWO MODELING METHODS FOR THE PREDICTION OF DEGREE-HOURS AND HEAT-STRESS LIKELIHOOD IN A SWINE BUILDING , 2004 .

[4]  M. Tielen,et al.  Influence of daily intermittent draught on the health status of weaned pigs , 1991 .

[5]  Daniel Berckmans,et al.  Sensor for Continuous Measurement of the Ventilation Rate in Livestock Buildings , 1991 .

[6]  P. Herpin,et al.  Effects of climatic conditions on the performance, metabolism and health status of weaned piglets: a review , 1994 .

[7]  J. M. Randall,et al.  Selection of piggery ventilation systems and penning layouts based on the cooling effects of air speed and temperature , 1980 .

[8]  A. Collin,et al.  Effects of high temperature on body temperature and hormonal adjustments in piglets. , 2002, Reproduction, nutrition, development.

[9]  Albert J. Heber,et al.  AIR QUALITY AND EMISSION MEASUREMENT METHODOLOGY AT SWINE FINISHING BUILDINGS , 2001 .

[10]  Daniel Berckmans,et al.  Data-based modeling of the spatiotemporal temperature distribution in a reach-in plant growth chamber , 2002 .

[11]  A. V. van Wagenberg,et al.  MEASUREMENT OF AIR VELOCITY IN ANIMAL OCCUPIED ZONES USING AN ULTRASONIC ANEMOMETER , 2003 .

[12]  S Pedersen [Climatization of animal houses: on basis of the CIGR Standard [Western Europe, conditioning technique, emission of heat]]. [Danish] , 1985 .

[13]  A. Van Brecht,et al.  CLIMATE CONTROL BASED ON TEMPERATURE MEASUREMENT IN THE ANIMAL-OCCUPIED ZONE OF A PIG ROOM WITH GROUND CHANNEL VENTILATION , 2005 .

[14]  van E.N.J. Ouwerker ANIPRO : klimaat- en energiesimulatiesoftware voor stallen , 1999 .

[15]  W. Hel,et al.  Acclimation of young pigs to fluctuating temperature and draught. , 1987 .

[16]  C. E. van 't Klooster,et al.  Implementation of natural ventilation in pig houses , 1994 .

[17]  Yuanhui Zhang,et al.  Commissioning Livestock Buildings: The Needs and Challenges , 2000 .

[18]  Hongwei Xin,et al.  ACUTE SYNERGISTIC EFFECTS OF AIR TEMPERATURE, HUMIDITY, AND VELOCITY ON HOMEOSTASIS OF MARKET-SIZE BROILERS , 2003 .

[19]  G. Bot,et al.  Measurements and Simulation of Climatic Conditions in the Animal Occupied Zone in a Door Ventilated Room for Piglets , 2004 .

[20]  J. A. Nienaber,et al.  Feeding Patterns and Swine Performance in Hot Environments , 1996 .

[21]  Sue J. Welham,et al.  Genstat 5 release 3 reference manual , 1994 .

[22]  J. M. Bruce,et al.  Models of heat production and critical temperature for growing pigs , 1979 .

[23]  H. Gaskins,et al.  Diet-dependent and diet-independent metabolic responses underlie growth stasis of pigs at weaning. , 1995, The Journal of nutrition.

[24]  L. Lefaucheur,et al.  Adaptative changes in oxidative metabolism in skeletal muscle of cold-acclimated piglets , 1992 .

[25]  F. Kreith,et al.  Principles of heat transfer , 1962 .