黑龙江省农业高校科技信息服务协同模式探索

黑龙江省农业高校为现代化大农业建设做出了巨大贡献,创新和完善了以农技推广中心、国营农场、农业合作组织为纽带的科技信息服务协同模式。通过对技术产品研发、培训教育和技术咨询等服务内容的研究,分析其采用项目带动、典型示范、科教培训、技术入股、教育网络联盟的多元结合方式,并在基础环境、业务制度、组织人才和资金等方面采取了有力的保障措施。     

基于合成法的定位误差的分析与计算

为保证机床夹具设计的可靠性,定位误差的计算是机床夹具设计过程中必不可少的重要环节之一。为此从定位误差的产生机理出发,介绍了定位误差的概念、产生原因,并给出计算公式,有助于快速实现定位误差的求解。     

多线左旋螺纹的数控车削方法

文章以沈阳数控机床HT1625 FANUC 0I-TC系统为例,通过选用设置合理的切削参数和工艺,探讨多线左旋螺纹的数控车削加工。     

“四全”育人夯实立德树人德育基础——以苏州工业职业技术学院为例

随着社会发展的推动和各种思想文化的交流、交融与交锋,给高职院校的思想政治教育工作带来前所未有的挑战。苏州工业职业技术学院积极探索实践"全员、全程、全方位、全心全意"育人的德育体系,在立德树人背景下,以踏实、务实、求实的作风不断夯实德育基础,努力开创"责任到人,纵向到底,横向到边"的德育工作局面。     

全运会竞赛制度变迁方向探索

通过对历届全运会竞赛规程的竞赛举办时间、地点、项目设置、运动员参赛资格、奖励和计分办法等条款进行分析，认 为全运会经过不断演变，已形成奥运会次年办赛、项目设置以夏季奥运项目为主并兼顾民族传统体育项目和全国各地竞争办赛 的特点；运动员交流办法已趋于完善，奥运会成绩计分、两次计分、球类加倍计分等计分办法逐渐演变成我国全会运会特殊的 计分制度。建议将已经有过办赛经验的省、市援助中、西部欠发达地区申办全运会，制定办赛奖励制度；对交流运动员交流年 限延长至一个全运会周期，重视“新型联合培养”；根据全运会发展需要，进一步加大计分奖励力度。     

东风454拖拉机前驱动桥下端盖漏油原因分析及改进措施

通过现场调查和结构分析,指出东风454拖拉机前驱动桥下端盖漏油原因是有零件损伤和结构设计上的缺陷共同造成的,在提出了不同的改进措施同时,并进行了可行性和成本对比分析。     

山药整地机械化作业技术规范

从作业条件、作业准备、作业方法等方面，介绍山药整地机械化作业技术的要点，论述其整地质量要求及相关参数计算方法，为山药种植产业的规范化及扩大化提供参考。     

沈阳铁西区装备制造产业聚集实证分析

铁西区通过打造装备制造业产业聚集区。形成了高档数控机床、通用石化装备等六大主导产业以及电气及新能源等五大千亿产业集群，成为我国老工业基地振兴的区域典范。介绍铁西装备制造业聚集区发展现状，采用区位熵法测算沈阳装备制造业的产业集中度，对全市装备制造业的现状及问题进行分析，得出相应结论。     

A trait-based characterization of cover plants to assess their potential to provide a set of ecological services in banana cropping systems

Cover plants are one of the means to increase the functional biodiversity of fields and to enhance the ecological functions of the communities. However, the design of cropping systems including cover plants relies largely on expert knowledge. There is a lack of methods to select the best suited cover plants according to their role in the agrosystem. We propose to use functional traits to select cover plants suited to sustain ecological services in the banana agrosystems of the French West Indies. Our objectives were (i) to characterize a collection of cover plants on a trait basis, according to their potential to provide the services expected in a banana agrosystem and (ii) to discuss the potential use of this characterization for the design of innovative multi-species banana cropping systems. In these systems, four main services are targeted, i.e. controlling weeds, controlling plant-parasitic nematodes, improving soil fertility and particularly N availability, and avoiding competition with banana for resource acquisition. Three experiments were conducted, under field and controlled conditions, to evaluate the potential of a collection of 28 tropical cover plants to achieve the functions related to these services. For each cover plant, a functional profile was constructed from a combination of plant traits that are easy to assess experimentally. It described plants’ potential to achieve the functions expected in a banana agrosystem. Functional profiles required for cover plant usages were also identified. The comparison of the plant functional profiles and the functional profiles required for their usages enabled us to select the best suited plants for each usage. However, these functional profiles rarely corresponded, meaning that a cover plant is rarely sufficient to achieve all the functions required for a usage. Functional complementarities obtained by the mixture of different species of cover plants are thus often required. Compared to classical approaches of innovative cropping system design based on the experimental testing of spatial and temporal plant combinations, such a trait-based approach saves time by focusing on a shortlist of cover plants best suited according to their functions in the agrosystem.     

Movement and survival of corn rootworm in seed mixtures of SmartStax® insect-protected corn

SmartStax^® insect-protected corn (Zea mays L.) contains genes for six Bacillus thuringiensis (Bt) proteins controlling both lepidopteran pests and the corn rootworm complex (Diabrotica spp.). The properties of SmartStax, particularly the multiple effective modes of action (i.e., each Bt protein provides a high level of control of the target pests with a low probability of cross-resistance among the proteins), have provided the opportunity to add to previously approved structured refuge options by combining the non-Bt refuge seed with SmartStax seed in a seed mix. Seed mixes ensure that a refuge is present in every Bt field, remove concerns about grower compliance with refuge requirements, and provide grower convenience. However, seed mixes could increase the likelihood that larval insects move between Bt and non-Bt plants and vice versa. Assessing the insect resistance management (IRM) value of a seed mix refuge requires an assessment of the amount of larval movement, and the consequences of that movement, for the key target pests. The studies here present such data for control of corn rootworm by SmartStax corn, which contains the rootworm-active protein Cry3Bb1 and the binary protein Cry34Ab1/Cry35Ab1. In a growth chamber experiment, SmartStax was most effective against first instars and significantly effective against second instars, but did not control third instars. In a field study of movement from a heavily infested non-Bt plant onto surrounding plants, a larger percentage of insects successfully dispersed from the infested plant when the surrounding plants were non-Bt plants than when they were SmartStax plants. A paired-plant study showed that few larvae migrated from infested SmartStax plants and survived on nearby non-Bt plants; larvae that migrated from infested non-Bt plants had low survival if the adjacent plants were SmartStax. Replicated field studies of plant-to-plant movement indicated that the non-Bt plants in a 5% or 10% seed mix consistently supported large populations of susceptible insects and represented a productive refuge, whereas the SmartStax plants had few or no survivors. The timing of emergence from seed mix plots containing 5% or 10% non-Bt plants was more similar to that of the non-Bt plots than that of the SmartStax plots. Thus, the available growth chamber and field data indicate that a seed mix of 5% or more will provide an effective refuge for corn rootworm in SmartStax corn.