提高动物福利的可穿戴产品研究进展

摘要/Abstract

摘要： 为提高动物福利水平，降低动物疫病风险，从动物情感需求、生理需求和智能化疾病诊断角度出发，对动物可穿戴产品进行分析研究。在消减动物心理问题、监测动物行为和生命体征等方面，综述了可穿戴产品在提升动物福利方面的方法原理。分析发现：目前的技术水平虽然在理想状态下能够提高动物福利，但实际环境干扰因素多、产品续航低、穿戴时容易引起动物应激反应等问题，远不能满足动物在特殊环境下的功能需求。最后指出动物可穿戴产品所面临的挑战和未来的发展方向，以期为动物福利水平改善提供一定的理论指导。

关键词: 动物福利, 心理需求, 诊断技术, 服装设计, 功能面料

Abstract: To improve the level of animal welfare and reduce the risk of animal diseases, this paper presents wearable animal products from the perspective of animal emotional needs, physiological needs and intelligent disease diagnosis.
The first is the analysis of pet clothing based on the pets' emotional needs. The design takes into account the needs of owners and pets, such as easiness to wear and take off, dirty and wear resistance, easiness to store, etc. At the same time, it should also reflect the practicality and convenience of clothes, pay attention to science, rationality and humanization, so that the owners can experience the sense of care and participation in the process of wearing for pets, so as to get a kind of emotional satisfaction. The emotional needs of pets are mainly reflected in "separation anxiety". To address such problems, it is necessary to explore feasible treatment methods in terms of materials, structure, color, etc. of animal clothing. Second, animal clothing is based on physiological needs. At present, the main objects of animal clothing design are pet cats and dogs, and different varieties have great differences in body shape, which makes it necessary to produce various sizes of clothing in production, and is easy to cause economic losses and bring difficulties to production and sales. In addition, the animal clothing materials used are generally the same as those of the staff, but due to the great differences in the physiological characteristics of humans and animals, the existing animal clothing materials can not fully adapt to the functional requirements of animals in different specific environments. Finally, smart wearable devices are used to diagnose animal diseases of animal behavior and vital signs. With the gradual expansion of the smart wearable field in the market of pet products, smart wearable products have an important application value in monitoring physical and mental health and vital signs. In terms of wearable products that monitor animal behavior, most wearable clothing include sound sensors and acceleration sensors. This kind of monitoring method has high monitoring accuracy, but the equipment generally has low battery life and needs to be replaced frequently. And there is a large number of animals in the farm, so the frequent replacement of products brings great inconvenience to the staff. In addition, in the aspect of wearable products for monitoring animal vital signs, wearable sensors are usually used to measure animal body temperature, which can achieve high accuracy. However, the stress reaction of animals may lead to the displacement of the sensor, which in turn affects the measurement accuracy. At the same time, the high cost and endurance of the products are also one of the main reasons that affect its application.
The research shows that the development trend of wearable products for animal welfare can be summarized into three aspects. First, animal clothing should better meet the spiritual needs of animals, so as to alleviate the common psychological problems of pets. On this basis, a method of combining flexible garment materials and adjustable garment structure is proposed to solve the problem of multitype production. Second, based on the needs of animal living environment and physiological characteristics, the functional clothing fabrics are developed, so as to improve the welfare level of animals and better protect and help them. Third, the use of energy conversion technology to achieve wearability can reduce the number of wearable clothing changes for animals. At the same time, we will also explore the use of functional materials to replace the sensors in biological wearable devices, such as thermochromic materials, to realize the temperature detection of biological wearable devices, so as to solve the problems of expensive and frequent replacement of biological wearable devices.

Key words: animal welfare, psychological need, diagnostic technology, clothing design, functional fabric

中图分类号:

TS184

沙莎 , 刘梦婕, 迟诚, 刘雅婷. 提高动物福利的可穿戴产品研究进展[J]. 现代纺织技术, 2024, 32(2): 18-26.

SHA Shaa, b, LIU Mengjiea, b, CHI Chengb, LIU Yatingc. Progress in wearable products to improve animal welfare[J]. Advanced Textile Technology, 2024, 32(2): 18-26.

参考文献

[1]王宁飞,常禹,吴彦雄,等.现代畜牧业发展及动物福利伦理研究[J].中国动物保健,2022,24(10):75-76,80.
WANG Ningfei, CHANG Yu, WU Yanxiong, et al. Modern animal husbandry development and animal welfare ethics research [J].China Animal Health, 2022,24 (10):75-76,80.
[2]李奇峰, 李嘉位, 马为红, 等. 畜禽养殖疾病诊断智能传感技术研究进展[J]. 中国农业科学, 2021, 54(11):2445-2463.
LI Qifeng, LI Jiawei, MA Weihong, et al. Research progress of intelligent sensing technology for diagnosis of livestock and poultry diseases[J]. Scientia Agricultura Sinica, 2021, 54(11):2445-2463.
[3]杨雪涛. 新型宠物服装的开发研究[D]. 无锡: 江南大学, 2008.
YANG Xuetao. Development and Research of the New Style Pet Clothes[D]. Wuxi: Jiangnan University, 2008.
[4]汪佳惠,陈懿,陈欣怡,等.基于问卷调查的宠物服饰消费行为及心理需求分析[J].化纤与纺织技术,2023,52(1):70-73.
WANG Jiahui, CHENYi, CHENYi Xinyi, etc. Analysis of the consumption behavior and psychological demand of pet clothing based on the questionnaire survey [J]. Chemical Fiber & Textile Technology, 2023,52 (1):70-73.
[5]申炎平. 亲宠服装情感化设计研究:以宠物犬服装为例 [D]. 上海: 东华大学, 2021.
SHEN Yanping. Research on Emotional Design of Pet Parent-child Clothing: Taking Pet Dog Clothing as an Example[D]. Shanghai: Donghua University, 2021.
[6]屈思雨. 基于情感需求的家宠服饰品设计研究[D]. 杭州: 浙江理工大学, 2018.
QU Siyu. The Application Research of Pet Clothing Design based on the Emotional Demand[D]. Hangzhou: Zhejiang Sci-Tech University, 2018.
[7]DAIGLE C L, RIDGE E E. Investing in stockpeople is an investment in animal welfare and agricultural sustainability [J]. Animal Frontiers, 2018, 8(3): 53-59.
[8]LECONSTANT C, SPITZ E. Integrative model of human-animal interactions: A one health-one welfare systemic approach to studying HAI [J]. Frontiers in Veterinary Science, 2022, 9, 656833.
[9]REHN T, KEELING L J. Measuring dog-owner relationships: Crossing boundaries between animal behaviour and human psychology [J]. Applied Animal Behaviour Science, 2016, 183:1-9.
[10]VAATAJA H, MAJARANTA P, CARDO AV, et al. The interplay between affect, dog's physical activity and dog-owner relationship [J]. Frontiers in Veterinary Science, 2021, 8: 673407.
[11]王艺轩. 情感交流下的宠物犬智能穿戴产品设计研究[D]. 武汉: 武汉纺织大学, 2021.
WANG Yixuan. Research on the Design of Intelligent Wearable Pet Dog Products based on Emotional Communication[D]. Wuhan: Wuhan Textile University, 2021.
[12]KIM J M, PARK S. The prototype development of clothing for pet dogs [J]. The Research Journal of the Costume Culture, 2010, 18(4): 599-611.
[13]LEE J E. A study on the development of pattern and design for pet dog's wear[J]. Journal of the Korean Society for Clothing Industry, 2012, 14(5):846-852.
[14]林琳. 宠物犬风雨衣研究与设计[D]. 上海: 东华大学, 2020,
LIN Lin. Research and Design of Pet Dog Raincoat[D]. Shanghai: Donghua University, 2020.
[15]姜茂欣, 鲁虹, 黄婉蓉, 等. 基于LilyPad Arduino的宠物狗智能夜行服研发 [J]. 现代纺织技术, 2021, 29(3): :65-70.
JIANG Maoxin, LU Hong, HUANG Wanrong, et al. Development of intelligent night wear for pet dogs based on LilyPad Ardunio[J]. Advanced Textile Technology, 2021, 29(3): 65-70.
[16]Foutz Timothy L, Budsberg Steven C. Impact of wearing a service vest on three-dimensional truncal motion in dogs [J]. American Journal of Veterinary Research, 2020, 81(3):210-219.
[17]王明凯, 郭崧. 湿多孔表面循环蒸发降温防热面料在工作犬中的应用实践[J]. 中国工作犬业, 2019(3): 48-51.
WANG Mingkai, GUO Song. The application practice of wet porous surface circulating evaporation cooling heat-proof fabric in working dogs[J]. China Working Dog, 2019(3):48-51.
[18]王春亮, 张军, 熊前, 等. 高温环境中佩戴犬降温马甲对德国牧羊犬运动前后生理生化指标的影响 [J]. 江西畜牧兽医杂志, 2019(1): 24-27.
WANG Chunliang, ZHANG Jun, XIONG Qian, et al. Effects of wearing dog cooling vest in high temperature environment on physiological and biochemical indexes of German shepherd dogs before and after exercise[J]. Jiangxi Journal of Animal Husbandry & Veterinary Medicine, 2019(1):24-27.
[19]BENITO M, LOZANO D, MIRO F. Clinical evaluation of exercise-induced physiological changes in military working dogs (MWDS) resulting from the use or non-use of cooling vests during training in moderately hot environments [J]. Animals, 2022, 12(18): 2347.
[20]王营广. 浅谈军犬在特战侦察分队常规任务中的应用[J]. 中国工作犬业, 2020(12):39-43.
WANG Yingguang. Application of military dogs in conventional tasks of special warfare reconnaissance unit[J]. China Working Dog, 2020(12):39-43.
[21]汪冰倩. 浅谈各国军犬高科技装备[J]. 中国工作犬业, 2021(5):15-16.
WANG Bingqian. High-tech equipment of military dogs in various countries[J]. China Working Dog, 2021(5):15-16.
[22]张慧,刘献飞,燕红雁,等.相变材料对热防护服热蓄积性能的影响[J].消防科学与技术,2023,42(3):374-378.
ZHANG Hui, LIU Xianfei, YAN Hongyan, et al. Effect of phase change materials on the thermal storage properties of thermal protective clothing [J]. Fire Protection Science and Technology, 2023,42 (3):374-378.
[23]刘拓,郭文文,梁付巍,等.消防服隔热层材料研究进展[J].化工新型材料,2021,49(S1):1-4.
LIU Tuo, GUO Wenwen, LIANG Fuwei, et al. Research progress of thermal insulation materials of fire service [J]. New Chemical Materials, 2021,49 (S1):1-4.
[24]陈晓阳,顾宪红,孙福昱.中国西南地区奶牛场奶牛冷热应激程度与防暑防寒情况调研报告[J].中国奶牛,2021(10):5-8.
CHEN Xiaoyang, GU Xianhong, SUN Fuyu. Research report on heat and cold stress and heat prevention of dairy cows in dairy farms in Southwest China [J]. China Dairy Cattle, 2021 (10):5-8.
[25]王铜铜, 郭英, 任立明, 等. 奶牛福利与养殖现代化建设[J]. 中国乳业, 2016(7):30-33.
WANG Tongtong, GUO Ying, REN Liming, et al. Dairy cattle welfare and breeding modernization[J]. China Dairy Cattle, 2016(7):30-33.
[26]王莉薇,谢秋菊,刘洪贵,等.基于多源信息感知的奶牛反刍行为可穿戴式监测装置的研究[J].黑龙江畜牧兽医,2019(7):47-51,164.
WANG Liwei, XIE Qiuju, LIU Honggui, et al. A wearable monitoring device for cow rumination behavior based on multi-source information perception [J]. Heilongjiang Animal Science and Veterinary Medicine, 2019 (7):47-51,164.
[27]SHEN W Z, ZHANG A J, ZHANG Y, et al. Rumination recognition method of dairy cows based on the change of noseband pressure [J]. Information Processing in Agriculture, 2020, 7(4): 479-490.
[28]张森. 基于可穿戴声压传感器和LoRa网络的奶牛反刍监测系统研究[D]. 呼和浩特: 内蒙古大学, 2018.
ZHANG Sen. Research on Ruminant Monitoring System based on Wearable Pressure Sensor and Lora Network[D]. Hohhot: Inner Mongolia University, 2018.
[29]TSAI Y C, HSU J T, DING S T, et al. Assessment of dairy cow heat stress by monitoring drinking behaviour using an embedded imaging system [J]. Biosystems Engineering, 2020,199: 97-108.
[30]NASIRAHMADI A, HENSEL O, EDWARDS S A, et al. Automatic detection of mounting behaviours among pigs using image analysis [J]. Computers and Electronics in Agriculture, 2016, 124: 295-302.
[31]DENIZ N N, CHELOTTI J O, GALLI J R, et al. Embedded system for real-time monitoring of foraging behavior of grazing cattle using acoustic signals [J]. Computers and Electronics in Agriculture, 2017, 138:167-174.
[32]李赞. 一种柔性贴片式在线测量方式在生猪体温测量中的应用研究[D]. 长春: 吉林农业大学, 2018.
LI Zan. Application of a Flexible Patch Online Measurement Method in Pig Body Temperature Measurement[D]. Changchun: Jilin Agricultural University, 2018.
[33]SATHIYABARATHI M, JEYAKUMAR S, MANIMARAN A, et al. Infrared thermal imaging of udder skin surface temperature variations to monitor udder health status in Bos indicus (Deoni) cows[J]. INFRARED PHYSICS & TECHNOLOGY, 2018, 88:239-244.
[34]张宏, 沈明霞, 陆明洲, 等. 穿戴式猪用心电监测系统设计[J]. 南京农业大学学报, 2016, 39(5):872-879.
ZHANG Hong, SHEN Mingxia, LU Mingzhou, et al. Design of wearable pig ECG monitoring system[J]. Journal of Nanjing Agricultural University, 2016, 39(5):872-879.
[35]范霖, 陈向东, 李宁. 基于快速响应湿度传感器的无线呼吸检测系统[J]. 传感器与微系统, 2015, 34(3):84-86.
FAN Lin, CHEN Xiangdong, LI Ning. Wireless respiration detection system based on fast response humidity sensor[J]. Transducer and Microsystem Technologies, 2015, 34(3):84-86.