通过增强人类在设计、分析方面的能力,在线人工智能工具正在迅速改变机械工程、 制造业和维护。与传统方法相比,这些人工智能系统可以更快地处理海量数据、识别复杂模式并生成新的解决方案。例如,人工智能可以帮助您优化性能和可制造性设计,加速复杂的模拟,预测材料特性,并自动执行各种分析任务。
以下示例提示将提供生成式设计支持、加速仿真(有限元分析/计算流体动力学)、助力预测性维护(通过人工智能分析机械传感器数据预测潜在故障,实现主动维护并最大限度减少停机时间)、辅助材料选择等诸多功能。.
概念设计与头脑风暴
[prompt_formatter title=”新型机构概念生成” description=”提出多种机械概念以实现特定运动或任务,拓展工程师的解决方案空间。 详细阐述每种机制的运作原理、优势与局限。” temperature=”0.8” thinking=”high"]## 任务描述⸻生成实现指定运动或任务的新颖机械概念。为每个概念提供详细的运作原理、优势及局限性说明。⸻⸻## 输入要求⸻1. **特定运动或任务**:机构需实现的运动或任务:{specific_motion_or_task}。⸻2. **约束与要求**:必须考虑的约束或要求:{constraints_and_requirements}。⸻⸻## 输出⸻1. **概念清单**:生成至少三个创新机械概念的列表。⸻2. **工作原理**:针对每个概念详细描述其工作原理。⸻3. **优缺点**:为每个概念提供全面的优缺点清单。⸻⸻## 操作指南⸻1. 分析指定运动或任务及其约束条件。⸻2. 生成多样化的机械概念方案以实现该运动或任务。⸻3. 针对每个概念详细阐述工作原理,重点说明其实现运动或任务的方式。⸻4. 列出优缺点,考量效率、复杂度、成本及可靠性等因素。⸻5. 确保方案具创新性,突破传统解决方案的局限。⸻⸻## 注意事项⸻- 注重创意性与可行性。⸻- 酌情采用跨学科方法。⸻- 必要时使用示意图或草图阐释复杂概念。[/prompt_formatter]
[prompt_formatter title=”仿生学在工程设计中的应用” description=”识别已解决类似工程问题的生物系统,从自然中汲取创新设计的灵感。 阐释自然机制及其在技术应用中的转化路径。” temperature=”0.7” thinking=”high"]## 任务概述⸻识别有效应对{your_engineering_problem}等工程挑战的生物系统。剖析这些自然机制的运作原理,并提出技术应用的转化方案。⸻⸻## 输入要求⸻1. 明确具体工程问题:{your_engineering_problem}。⸻2. 指定解决方案的约束条件:{constraints_and_requirements}。⸻⸻## 输出结构⸻1. **生物系统识别**⸻ – 识别并描述解决类似问题的生物系统。⸻ – 阐明其运作的自然机制。⸻⸻2. **机制分析**⸻ – 评估这些机制的效率与效能。⸻ – 探讨其运作的环境条件。⸻⸻3. **适应性方案**⸻ – 提出如何将这些自然机制适应于给定的工程挑战。⸻ – 建议受这些系统启发的潜在材料、结构或工艺。⸻⸻4. **可行性评估**⸻ – 评估实施所提适应方案的可行性。⸻ – 考虑技术、经济和环境因素。⸻⸻## 补充说明⸻- 使用科学术语并引用相关研究或生物学文献。⸻- 确保对机制与适应方案的阐述清晰精准。⸻- 突出所提解决方案的创新性。[/prompt_formatter]
[prompt_formatter title="产品设计规范 (PDS) 大纲" description="生成一个全面的模板,用于 产品设计 产品规格说明书 (PDS) 文件。该文件确保所有关键要求,例如性能指标、材料限制和安全要求。 标准,在项目开始时定义。# 产品设计规范 (PDS) 大纲模板生成 # 目标 # 生成详细的产品设计规范 (PDS) 模板,以定义所有关键项目需求,包括性能指标、材料限制和安全标准。# 说明 # 1. **项目概述** # 简要描述项目,包括其目的和范围。 # 定义目标市场和用户需求。 # 2. **性能指标** # 列出产品必须达到的所有关键性能指标。包括量化目标和测量方法。⸻⸻3. **材料限制**⸻ 明确任何材料要求或限制。⸻ 考虑耐用性、成本和环境影响等因素。⸻⸻4. **安全标准**⸻ 确定相关的安全标准和 法规.⸻ 概述合规性要求和测试程序。⸻⸻5. **功能要求**⸻ 详细说明产品必须执行的基本功能。⸻ 包括 user interface 和 可用性 6. 环境因素考量 • 考虑环境影响和可持续性目标。 • 包括生命周期分析和报废处置计划。 7. 成本和预算限制 • 明确预算限制和成本目标。 • 考虑生产、维护和运营成本。 8. 时间表和里程碑 • 制定包含关键里程碑的项目时间表。包含项目各阶段的截止日期。⸻⸻## 输出格式⸻以结构化格式提供产品数据声明 (PDS) 模板,以便用户根据项目具体情况进行自定义。⸻⸻## 用户输入⸻在适用情况下,将占位符替换为具体的项目信息。⸻⸻## 其他说明⸻确保模板适用于各种类型的产品和行业。
[prompt_formatter title=”系统架构头脑风暴” description=”为复杂产品设计多个高层次系统架构,展示子系统的不同组合方式。必要时生成Mermaid格式图表。 这有助于在早期阶段比较模块化、集成化及其他设计理念之间的权衡取舍。” temperature=”0.7” thinking=”high“]**任务概述**⸻基于给定子系统,为复杂产品生成高层次系统架构。探索多种布局方案,比较模块化、集成化及其他设计理念的权衡取舍。必要时使用Mermaid格式生成示意图。⸻⸻**输入要求**⸻1. 子系统清单:{list_of_subsystems}⸻2. 待探索的设计理念:{design_philosophies}⸻3. 具体约束条件或要求:{constraints_requirements}⸻⸻**输出**⸻1. 展示不同子系统组合方案的多套高层次系统架构。⸻2. 每套架构对应的Mermaid格式示意图(如适用)。⸻3. 针对每种设计理念的权衡分析,重点评估模块化、集成度及其他指定理念。⸻⸻**实施流程**⸻1. 分析子系统清单,识别潜在交互与依赖关系。⸻2. 针对每种设计理念,创建相应子系统布局的高级架构⸻3. 生成Mermaid格式图表以可视化呈现各架构⸻4. 评估各架构的权衡取舍,考量可扩展性、灵活性、复杂度及性能等因素⸻5. 总结研究结果并突出各架构间的关键差异⸻⸻**MERMAID 图表模板**⸻“`mermaid⸻graph TD⸻A[子系统 A] –> B[子系统 B]⸻B –> C[子系统 C]⸻“`⸻⸻**补充说明**⸻确保所有架构均符合指定约束与要求。 根据系统复杂度及分析需求调整图示细节程度。[/prompt_formatter]
[prompt_formatter title=#针对设计缺陷的头脑风暴解决方案# description=#针对已识别的特定设计缺陷,生成一系列富有创意且切实可行的解决方案。这通过提供广泛的潜在修复方案来加速问题解决过程。# temperature=# 0.8# thinking=# high# ]**任务概述**⸻通过生成一系列富有创意且切实可行的解决方案,识别并解决特定的设计缺陷。⸻⸻**输入要求**⸻1. 设计缺陷的描述:{design_flaw_description}⸻2. 设计背景(例如,产品类型、使用环境):{design_context}⸻3.约束条件和要求(例如,成本、材料、时间):{design_constraints}⸻⸻**输出预期**⸻生成一份既有创意又实用的潜在解决方案列表。每个解决方案应包含:⸻- 解决方案的简要描述⸻- 潜在优势⸻- 可能的缺点⸻- 实施可行性⸻⸻**流程**⸻1. 分析所提供的设计缺陷和背景。⸻2. 考虑约束条件和要求。⸻3. 集思广益,提出各种解决方案,确保兼顾创意性和实用性。⸻4. 根据可行性、优势和缺点评估每个解决方案。⸻5. 将解决方案整理成一个结构化的列表,并附上详细描述。⸻⸻**输出格式**⸻- 解决方案 1:⸻ – 描述:$solution1_description⸻ –优势:$solution1_benefits⸻ – 劣势:$solution1_drawbacks⸻ – 可行性:$solution1_feasibility⸻- 方案 2:⸻ – 描述:$solution2_description⸻ – 优势:$solution2_benefits⸻ – 劣势:$solution2_drawbacks⸻ – 可行性:$solution2_feasibility⸻- … (继续查看更多方案)⸻⸻**附加说明**⸻确保方案既具有创新性,又基于实际应用。考虑跨学科方法和新兴技术。 技术 (如适用)
材料和组件选择
[prompt_formatter title=#极端环境材料选择# description=#针对在特定极端条件下(例如高温、腐蚀性、高……)运行的部件,推荐并比较各种材料 压力输出结果提供了一个按关键属性和理由排序的材料列表。## 极端环境材料选择 ### 输入要求 - 定义组件将面临的具体极端条件:{extreme_conditions}(例如,高温、腐蚀性、高压)。 - 指定任何其他约束或要求:{additional_constraints}(例如,重量限制、成本考虑)。 ### 任务 1. 分析给定的极端条件和约束。 2. 确定适用于这些条件的潜在材料。 3. 根据热阻等关键属性比较材料, 耐腐蚀性机械强度和成本。⸻4. 根据指定条件,将材料按适用性从高到低排序。⸻5. 说明排序理由,重点阐述每种材料的优点和缺点。⸻⸻### 输出⸻- 包含材料关键性能及其排序理由的列表。⸻- 包含分析总结和最佳材料选择建议。⸻⸻### 示例⸻- 输入:{extreme_conditions} = “高温,腐蚀性”;{additional_constraints} = “低成本”⸻- 输出:⸻ 1. 材料 A:耐热性高,耐腐蚀性优异,成本适中。理由:在指定条件下性能平衡最佳。⸻ 2. 材料 B:耐热性中等,耐腐蚀性良好,成本低。理由:适合预算限制,但在高温下性能较差。⸻ 3. 材料 C:优异的耐热性,中等的耐腐蚀性,成本高。理由:性能卓越,但性价比不高。⸻⸻### 附加说明⸻- 确保分析考虑最新的材料科学研究和行业标准。⸻- 使用可靠的数据来源和参考文献来获取材料特性和性能信息。
[prompt_formatter title=#可持续材料替代方案# description=#针对特定应用提出环保且可持续的材料替代方案。它包含有关可回收性、隐含能源和生命周期影响的数据,以支持绿色设计选择。# temperature=# 0.7# thinking=# medium#]**任务概述**⸻针对特定应用,识别可持续的材料替代方案,重点关注可回收性、隐含能源和生命周期影响。⸻⸻**输入要求**⸻1. 定义应用背景:{application_context}。⸻2. 指定当前使用的材料:{current_materials}。⸻3. 列出任何具体的可持续性标准或限制:{sustainability_criteria}。⸻⸻**流程**⸻1.分析应用背景 (application_context) 以了解材料的功能需求。⸻2. 评估现有材料 (current_materials) 的环境影响,重点关注其可回收性、隐含能源和生命周期影响。⸻3. 研究符合可持续性标准 (sustainability_criteria) 和功能需求的替代材料。⸻4. 基于以下方面比较替代方案:⸻⸻ a. 可回收性:评估回收过程的便捷性和效率。⸻ b. 隐含能源:计算生产过程中消耗的总能源。⸻ c. 生命周期影响:评估材料在其整个生命周期中的环境影响。⸻⸻5. 提出最合适的可持续材料替代方案,并提供详细的数据和理由。⸻⸻**输出**⸻提供一份综合报告,详细说明:⸻1. 现有材料的分析。⸻2. 提出的可持续替代方案。⸻3.每种替代方案的可回收性、隐含能源和生命周期影响数据。⸻4. 对推荐材料进行对比分析,以证明其适用于{application_context}。⸻⸻**附加说明**⸻确保所有数据来源可靠且最新。如适用,请提供参考文献。[/prompt_formatter]
[prompt_formatter title=”现成组件采购” description=”识别符合特定技术要求的标准现成组件(例如轴承、紧固件、电机)。与定制零件相比,这可以节省时间和成本。” temperature=”0.7″ thinking=”medium”]**任务**⸻识别并选择符合指定技术要求的标准现成组件。⸻⸻**输入要求**⸻1.定义组件的技术规格和约束:{component_type}、{load_capacity}、{dimensions}、{material}、{operating_conditions}、{certifications}。⸻2.请提供任何其他偏好或限制:{preferred_brands}、{budget_limits}、{lead_time_constraints}。⸻⸻**流程**⸻1. 搜索符合已定义规格和限制的现有现成组件。⸻2. 根据组件与指定要求和其他偏好的兼容性对其进行评估。⸻3. 列出潜在供应商,并根据成本、可用性和技术要求的符合性比较他们的产品。⸻4.推荐最符合标准的顶级组件和供应商。⸻⸻**输出**⸻提供一份详细报告,内容包括:⸻- 已识别组件及其规格清单。⸻- 供应商信息和联系方式。⸻- 基于成本、可用性和合规性的组件比较。⸻- 最终推荐及其理由。⸻⸻**备注**⸻在最终确定推荐之前,请确保所有数据均为最新数据,并核实供应商的信誉。
Design for Manufacturing and Assembly (DFM/DFA)
[prompt_formatter title=”DFM/DFA Checklist Generation” description=”Creates a customized checklist for Design for Manufacturing and Assembly based on specified production processes (e.g., CNC machining, injection molding, sheet metal). This helps optimize designs for efficient and cost-effective production.” temperature=”0.3″ thinking=”medium”]**TASK**⸻Generate a customized Design for Manufacturing and Assembly (DFM/DFA) checklist.⸻⸻**INPUT REQUIREMENTS**⸻1. Specify the production process: {production_process} (e.g., CNC machining, injection molding, sheet metal).⸻2. List any specific design constraints or requirements: {design_constraints}.⸻3. Provide any relevant industry standards or guidelines: {industry_standards}.⸻⸻**OUTPUT**⸻Provide a detailed DFM/DFA checklist tailored to the specified production process, including:⸻- Key design considerations for {production_process}.⸻- Potential cost-saving opportunities.⸻- Common pitfalls and how to avoid them.⸻- Recommendations for improving manufacturability and assembly efficiency.⸻⸻**ADDITIONAL INSTRUCTIONS**⸻Ensure the checklist is comprehensive and considers all aspects of the specified production process.⸻Reference the provided {design_constraints} and {industry_standards} where applicable.⸻Focus on optimizing designs for both efficiency and cost-effectiveness.[/prompt_formatter]
[prompt_formatter title=”Tolerance Stack-up Analysis Guidance” description=”Outlines the steps, tips and best practices for performing a tolerance stack-up analysis on a mechanical assembly of a given type, process or industry. This provides a structured 方法 to ensure components fit and function correctly.” temperature=”0.3″ thinking=”medium”]# TOLERANCE STACK-UP ANALYSIS GUIDANCE⸻⸻## INPUT REQUIREMENTS⸻- Specify the type of mechanical assembly: {assembly_type}⸻- Define the industry or process context: {industry_or_process}⸻- Provide component specifications and tolerances: {component_specifications}⸻- List any known constraints or critical dimensions: {constraints_or_critical_dimensions}⸻⸻## ANALYSIS STEPS⸻1. **Component Identification**⸻ – List all components involved in the assembly.⸻ – Identify each component’s role and interaction within the assembly.⸻2. **Tolerance Data Collection**⸻ – Gather all relevant tolerance data for each component.⸻ – Ensure data accuracy and relevance to {industry_or_process}.⸻3. **Assembly Path Definition**⸻ – Define the assembly path and sequence.⸻ – Identify key interfaces and mating surfaces.⸻4. **Tolerance Stack-up Calculation**⸻ – Use worst-case, statistical, or Monte Carlo methods as applicable.⸻ – Calculate cumulative tolerances for the assembly.⸻5. **Analysis and Optimization**⸻ – Identify potential fit or function issues.⸻ – Propose adjustments or redesigns to optimize tolerance distribution.⸻6. **Documentation and Reporting**⸻ – Document the analysis process and results.⸻ – Prepare a report summarizing findings and recommendations.⸻⸻## BEST PRACTICES⸻- Use consistent units and measurement standards.⸻- Validate assumptions with empirical data or simulations.⸻- Collaborate with cross-functional 团队 for comprehensive insights.⸻- Regularly review and update tolerance data as designs evolve.[/prompt_formatter]
[prompt_formatter title=”Jigs and Fixtures Design Concepts” description=”Brainstorms different design concepts for jigs and fixtures needed to manufacture or assemble a specific component. This improves the efficiency, repeatability, and safety of production processes.” temperature=”0.7″ thinking=”medium”]# JIGS AND FIXTURES DESIGN CONCEPTS⸻⸻## OBJECTIVE⸻Generate innovative design concepts for jigs and fixtures to enhance the efficiency, repeatability, and safety of manufacturing or assembling {specific_component}.⸻⸻## INPUT REQUIREMENTS⸻1. Component Details: Provide detailed specifications, dimensions, and any unique features of {specific_component}.⸻2. Manufacturing/Assembly Process: Describe the current process or intended process for manufacturing or assembling {specific_component}.⸻3. Constraints: List any constraints such as material limitations, space restrictions, or budget considerations.⸻4. Safety Requirements: Specify any safety standards or considerations that must be adhered to.⸻⸻## OUTPUT EXPECTATIONS⸻1. Conceptual Designs: Generate at least three distinct design concepts for jigs and fixtures.⸻2. Efficiency Analysis: Provide a brief analysis of how each design concept improves efficiency.⸻3. Repeatability Assessment: Evaluate the potential for each design to enhance process repeatability.⸻4. Safety Evaluation: Assess the safety features and compliance of each design concept.⸻⸻## INSTRUCTIONS⸻1. Analyze the provided component details and process description to understand the specific needs.⸻2. Consider the constraints and safety requirements when generating design concepts.⸻3. Use creativity and engineering principles to brainstorm innovative solutions.⸻4. Document each design concept with sketches or diagrams if possible.⸻⸻## ADDITIONAL CONSIDERATIONS⸻- Explore the use of advanced materials or technologies that could enhance the design.⸻- Consider modularity and adaptability for future component variations.⸻- Evaluate the cost-effectiveness of each design concept.⸻⸻## FINAL OUTPUT⸻Provide a comprehensive report summarizing the design concepts, analyses, and evaluations.[/prompt_formatter]
[prompt_formatter title=”Post-Processing for Additive Manufacturing” description=”Details the necessary post-processing steps and rough time estimation for a 3D-printed part based on the chosen printing technology, specific material, and requirements.” temperature=”0.5″ thinking=”medium”]**TASK OVERVIEW**⸻Provide a detailed plan for post-processing a 3D-printed part.⸻Include necessary steps and time estimates based on the chosen printing technology, material, and specific requirements.⸻⸻**INPUT REQUIREMENTS**⸻1. Printing Technology: {FDM/SLA/SLS/other}⸻2. Material Type: {material_name}⸻3. Part Requirements: {requirements_description}⸻4. Part Complexity: {simple/medium/complex}⸻5. Surface Finish Quality: {standard/high}⸻6. Dimensional Tolerance: {tolerance_value}⸻⸻**OUTPUT EXPECTATIONS**⸻1. List of Post-Processing Steps:⸻- Describe each step in detail.⸻- Specify tools and materials needed.⸻2. Time Estimation:⸻- Provide rough time estimates for each step.⸻- Include total time estimation.⸻3. Additional Recommendations:⸻- Suggest improvements or alternatives if applicable.⸻- Highlight any potential challenges.⸻⸻**CONSTRAINTS**⸻- Ensure compatibility with the specified printing technology and material.⸻- Align with the given part requirements and quality standards.⸻- Consider efficiency and cost-effectiveness.⸻⸻**EXECUTION**⸻Analyze the input data to tailor the post-processing plan.⸻Use industry standards and best practices to inform recommendations.⸻Provide a concise and actionable output.[/prompt_formatter]
Simulation and Analysis
[prompt_formatter title=”Finite Element Analysis (FEA) Sanity Check” description=”Provides a list of common mistakes and critical checks to perform before and after running a 有限元 Analysis of a given part or industry. This helps ensure the accuracy and reliability of the simulation results.” temperature=”0.3″ thinking=”medium”]# FEA SANITY CHECK⸻⸻## INPUT REQUIREMENTS⸻- Part or Industry Description: {part_or_industry_description}⸻- Material Properties: {material_properties}⸻- Boundary Conditions: {boundary_conditions}⸻- Load Cases: {load_cases}⸻- Mesh Details: {mesh_details}⸻⸻## PRE-FEA CHECKS⸻1. **Geometry Verification**: Ensure the geometry is clean and free of defects such as gaps or overlaps.⸻2. **Material Properties**: Verify that the material properties are accurate and relevant to the part or industry.⸻3. **Boundary Conditions**: Check that all boundary conditions are correctly applied and reflect real-world constraints.⸻4. **Load Cases**: Confirm that all load cases are defined correctly and are representative of actual operating conditions.⸻5. **Mesh Quality**: Evaluate the mesh for quality, ensuring it is sufficiently refined in critical areas.⸻⸻## POST-FEA CHECKS⸻1. **Convergence Check**: Verify that the solution has converged by checking residuals and other convergence criteria.⸻2. **Result Validation**: Compare simulation results with known benchmarks or experimental data to validate accuracy.⸻3. **Stress and 菌株 Distribution**: Analyze 压力 and strain distributions for unexpected concentrations or anomalies.⸻4. **Deformation Patterns**: Review deformation patterns to ensure they are physically plausible.⸻5. **Sensitivity Analysis**: Conduct sensitivity analysis to understand the impact of varying parameters on results.⸻⸻## COMMON MISTAKES⸻- Incorrect application of boundary conditions.⸻- Over-simplification of the model leading to inaccurate results.⸻- Ignoring mesh quality, resulting in poor accuracy.⸻- Misinterpretation of results due to lack of 验证.⸻⸻## OUTPUT⸻Provide a summary of the checks performed and any identified issues or recommendations for improvement.⸻⸻## EXECUTION⸻Use the input data to perform the checks and provide a detailed report on the findings, ensuring all critical aspects are covered.[/prompt_formatter]
[prompt_formatter title=”CFD Boundary Condition Recommendations” description=”Suggests appropriate boundary conditions for a Computational Fluid Dynamics (CFD) analysis of a specific scenario (e.g., airflow over a heat sink). This is crucial for setting up an accurate and realistic simulation.” temperature=”0.7″ thinking=”high”]**TASK**⸻Provide expert-level recommendations for setting up boundary conditions in a Computational Fluid Dynamics (CFD) simulation for the specified scenario.⸻⸻**INPUT REQUIREMENTS**⸻1. Describe the specific CFD scenario: {scenario_description}.⸻2. Specify the fluid properties: {fluid_properties}.⸻3. Define the geometry and domain of the simulation: {geometry_and_domain}.⸻4. Identify any specific physical phenomena to be captured: {physical_phenomena}.⸻5. Note any constraints or assumptions: {constraints_assumptions}.⸻⸻**OUTPUT**⸻1. List the recommended boundary conditions for the given scenario.⸻2. Provide a rationale for each recommended boundary condition.⸻3. Suggest any additional considerations or adjustments for achieving realistic simulation results.⸻⸻**CONSIDERATIONS**⸻- Ensure that the boundary conditions align with the physical phenomena and constraints specified.⸻- Consider the impact of boundary conditions on the stability and accuracy of the simulation.⸻- Address potential challenges in implementing the boundary conditions within the specified geometry and domain.⸻⸻**FORMAT**⸻- Use bullet points for clarity.⸻- Separate each recommendation and rationale clearly.⸻- Include references to any relevant literature or best practices if applicable.[/prompt_formatter]
[prompt_formatter title=”Fatigue Life Prediction Checklist” description=”Outlines the key steps, data inputs, and analysis models required to perform a fatigue life prediction of a given type or scenario. This guides engineers in assessing the durability of components subjected to cyclic loading.” temperature=”0.3″ thinking=”medium”]## FATIGUE LIFE PREDICTION CHECKLIST⸻⸻### OBJECTIVE⸻Provide a comprehensive checklist for predicting the fatigue life of components subjected to cyclic loading. This includes identifying key steps, necessary data inputs, and suitable analysis models.⸻⸻### INPUT REQUIREMENTS⸻1. **Component Details**: Describe the component, including material properties, geometry, and surface finish.⸻2. **Loading Conditions**: Specify the type of cyclic loading (e.g., tension-compression, bending, torsion) and loading spectrum.⸻3. **Environmental Factors**: Note any environmental conditions affecting the component (e.g., temperature, corrosion).⸻4. **Historical Data**: Provide any available fatigue test data or historical performance data.⸻⸻### CHECKLIST STEPS⸻1. **Material Characterization**:⸻- Gather material properties such as Young’s modulus, 屈服强度, ultimate tensile strength, and fatigue limit.⸻- Identify any material treatments or coatings.⸻⸻2. **Load Analysis**:⸻
– Determine the stress range and mean stress for the loading conditions.⸻- Calculate stress concentration factors if applicable.⸻⸻3. **Fatigue Analysis Model Selection**:⸻- Choose an appropriate fatigue life prediction model (e.g., S-N curve, strain-life approach, fracture 力学).⸻- Justify the selection based on component characteristics and loading conditions.⸻⸻4. **Data Input Preparation**:⸻- Prepare input data for the chosen model, ensuring accuracy and completeness.⸻- Consider any necessary data transformations or normalizations.⸻⸻5. **Simulation and Analysis**:⸻- Perform fatigue life simulations using the selected model and input data.⸻- Analyze results to identify potential failure points and life expectancy.⸻⸻6. **Validation and Verification**:⸻- Compare simulation results with historical data or experimental results for validation.⸻
– Adjust model parameters if discrepancies are found.⸻⸻7. **Documentation and Reporting**:⸻- Document the analysis process, assumptions, and results.⸻- Prepare a comprehensive report detailing the fatigue life prediction and recommendations.⸻⸻### OUTPUT⸻- A detailed checklist and report summarizing the fatigue life prediction, including identified failure points, life expectancy, and recommendations for design improvements or further testing.⸻⸻### ADDITIONAL NOTES⸻- Ensure all data inputs are accurate and reflect real-world conditions as closely as possible.⸻- Consider the use of 软件 tools for complex simulations and data analysis.⸻⸻### END OF CHECKLIST⸻[/prompt_formatter]
[prompt_formatter title=”Thermal Management Strategy Brainstorming” description=”Proposes various active and passive cooling strategies for a system that generates heat of a given type. It compares methods like heat sinks, heat pipes, and forced convection to find the optimal solution.” temperature=”0.7″ thinking=”high”]**TASK**⸻Analyze and propose optimal thermal management strategies for a system that generates heat.⸻⸻**INPUT REQUIREMENTS**⸻1. Specify the type of heat generated by the system: {heat_type}.⸻2. Provide system specifications including dimensions, material properties, and operating conditions: {system_specifications}.⸻3. List any constraints or requirements for the cooling solution (e.g., size, weight, cost): {constraints}.⸻⸻**ANALYSIS**⸻1. Evaluate the effectiveness of passive cooling methods:⸻ – Heat sinks: Consider material, fin design, and surface area.⸻ – Heat pipes: Assess thermal conductivity and integration feasibility.⸻2. Evaluate the effectiveness of active cooling methods:⸻ – Forced convection: Analyze fan or blower options, airflow requirements, and power consumption.⸻ – Liquid cooling: Consider 泵 capacity, coolant type, and heat exchanger efficiency.⸻⸻**COMPARISON**⸻1. Compare the proposed methods based on efficiency, cost, and feasibility.⸻2. Identify trade-offs and potential integration challenges.⸻⸻**OUTPUT**⸻Provide a detailed comparison and recommendation for the optimal thermal management strategy, including:⸻1. A summary of the proposed methods and their evaluations.⸻2. A recommended solution with justification based on the analysis.⸻⸻**ADDITIONAL CONSIDERATIONS**⸻- Suggest any innovative or emerging technologies that could be applicable.⸻- Discuss potential environmental impacts and sustainability of the proposed solutions.[/prompt_formatter]
CAD, GD&T, and Documentation
[prompt_formatter title=”GD&T Callout Recommendations” description=”Suggests appropriate Geometric Dimensioning and Tolerancing (GD&T) callouts for a part based on its function and mating interfaces. This ensures the design intent is clearly communicated for manufacturing and inspection” temperature=”0.5″ thinking=”medium”]**TASK OVERVIEW**⸻Analyze the part’s function and mating interfaces to recommend suitable GD&T callouts.⸻⸻**INPUT REQUIREMENTS**⸻1. Part Description: Provide a detailed description of the part, including its primary function and any critical features.⸻2. Mating Interfaces: Describe the interfaces where the part connects with other components, including any specific alignment or fit requirements.⸻3. Tolerancing Priorities: List any specific tolerancing priorities or constraints that must be considered.⸻⸻**OUTPUT**⸻1. Recommended GD&T Callouts: A list of GD&T callouts that align with the part’s function and mating interfaces.⸻2. Justification: A brief explanation for each recommended callout, detailing how it supports the design intent and manufacturing requirements.⸻⸻**PROCESS**⸻1. Analyze the provided part description and identify key functional features.⸻2. Evaluate the mating interfaces to determine necessary alignment and fit requirements.⸻3. Cross-reference tolerancing priorities with GD&T principles to ensure compliance.⸻4. Generate a list of GD&T callouts with justifications for each.⸻⸻**ADDITIONAL NOTES**⸻Ensure that all recommendations are compliant with the latest GD&T standards and best practices.⸻Consider any industry-specific requirements that may influence tolerancing decisions.[/prompt_formatter]
[prompt_formatter title=”Bill of Materials (BOM) Template” description=”Creates a structured Bill of Materials (BOM) template with standard and custom fields (to be provided) for a mechanical assembly specific to a provided industry. This helps in organizing parts, managing procurement, and estimating costs.” temperature=”0.3″ thinking=”medium”]**TASK**⸻Create a structured Bill of Materials (BOM) template for a mechanical assembly.⸻⸻**INPUT REQUIREMENTS**⸻1. Industry Type: {industry_type}⸻2. Standard Fields: {list_of_standard_fields}⸻3. Custom Fields: {list_of_custom_fields}⸻⸻**INSTRUCTIONS**⸻1. Analyze the provided {industry_type} to determine relevant components and materials typically used.⸻2. Compile a list of standard fields from {list_of_standard_fields} that are essential for a BOM in this industry.⸻3. Integrate {list_of_custom_fields} to address specific needs or requirements unique to the mechanical assembly.⸻4. Structure the BOM template to include sections for part numbers, descriptions, quantities, units of measure, and any additional fields specified.⸻5. Ensure the template facilitates easy updates and modifications for procurement and cost estimation purposes.⸻⸻**OUTPUT**⸻Provide a structured BOM template with the following sections:⸻- Header: Industry Type, Date, Project Name⸻- Body: Standard Fields, Custom Fields⸻- Footer: Notes, Revision History⸻⸻**FORMAT**⸻Use a tabular format for the BOM template with clear headings for each section and field.⸻⸻**ADDITIONAL NOTES**⸻Ensure the template is adaptable for future modifications and scalable for different project sizes.[/prompt_formatter]
[prompt_formatter title=”Technical Report Structure Template” description=”Generates a standard template for a formal engineering report specific to a provided industry. This provides a logical structure with all necessary sections, such as an introduction, methodology, results, and conclusion recommended in that industry.” temperature=”0.3″ thinking=”medium”]**TASK**⸻Generate a standard template for a formal engineering report specific to the {industry}.⸻⸻**INPUT REQUIREMENTS**⸻1. Industry: {industry}⸻2. Specific focus or topic of the report: {report_topic}⸻⸻**OUTPUT STRUCTURE**⸻1. **Title Page**⸻⸻2. **Abstract**⸻⸻3. **Table of Contents**⸻⸻4. **Introduction**⸻- Context and background of {report_topic} in {industry}⸻- Objectives of the report⸻⸻5. **Literature Review**⸻- Summary of existing research and developments in {industry} related to {report_topic}⸻⸻6. **Methodology**⸻- Detailed description of methods and processes used in the study⸻- Justification for chosen methods⸻⸻7. **Results**⸻- Presentation of data and findings⸻- Use of tables, graphs, and charts as necessary⸻⸻8. **Discussion**⸻- Interpretation of results⸻- Comparison with existing literature⸻- Implications for {industry}⸻⸻9. **Conclusion**⸻- Summary of key findings⸻- Recommendations for future work or applications⸻⸻10. **References**⸻- List of all sources cited in the report⸻⸻11. **Appendices**⸻- Additional material supporting the report⸻⸻**INSTRUCTIONS**⸻1. Customize each section with specific details relevant to {report_topic} and {industry}.⸻2. Ensure all sections are logically connected and comprehensive.⸻3. Follow industry standards for formatting and citation.[/prompt_formatter]
[prompt_formatter title=”Technical Standard Summary” description=”Summarizes a lengthy and complex technical standard into a concise overview, highlighting key requirements and implications for a specific given design.” temperature=”0.5″ thinking=”medium”]**TASK OVERVIEW**⸻Summarize a complex technical standard document, focusing on key requirements and implications for a specific design.⸻⸻**INPUT REQUIREMENTS**⸻1. Provide the full text or a link to the technical standard document: {technical_standard_document}⸻2. Specify the design or project context for which the summary is needed: {design_context}⸻⸻**PROCESS**⸻1. Analyze the provided technical standard document to identify sections relevant to the specified design context.⸻2. Extract key requirements, guidelines, and constraints that directly impact the design.⸻3. Identify any critical compliance or regulatory implications.⸻4. Summarize the findings into a concise overview, emphasizing the most important points for the design.⸻⸻**OUTPUT FORMAT**⸻- **Key Requirements**: $key_requirements⸻- **Design Implications**: $design_implications⸻- **Compliance Considerations**: $compliance_considerations⸻⸻**ADDITIONAL NOTES**⸻Ensure the summary is clear and directly applicable to the specified design context, avoiding unnecessary details that do not impact the design.⸻Use bullet points or numbered lists for clarity where appropriate.[/prompt_formatter]
System Integration and Safety
[prompt_formatter title=”Component Integration Checklist” description=”Generates a checklist for a given set of elements to ensure proper mechanical, electrical, and software integration between different subsystems.” temperature=”0.7″ thinking=”medium”]# COMPONENT INTEGRATION CHECKLIST GENERATOR⸻⸻## INPUT REQUIREMENTS⸻- List of subsystems involved: {list_of_subsystems}⸻- Mechanical components and interfaces: {mechanical_components}⸻- Electrical components and interfaces: {electrical_components}⸻- Software components and interfaces: {software_components}⸻- Integration standards or protocols: {integration_standards}⸻⸻## TASK⸻Generate a comprehensive checklist to ensure seamless integration of mechanical, electrical, and software components across the specified subsystems.⸻⸻## OUTPUT FORMAT⸻1. **Mechanical Integration**⸻ – Verify mechanical compatibility between {mechanical_components} across {list_of_subsystems}.⸻ – Ensure alignment and fit of mechanical interfaces.⸻ – Check for compliance with {integration_standards}.⸻⸻2. **Electrical Integration**⸻ – Confirm electrical connectivity and compatibility between {electrical_components}.⸻ – Validate power requirements and distribution across {list_of_subsystems}.⸻ – Ensure adherence to {integration_standards}.⸻⸻3. **Software Integration**⸻ – Assess software compatibility and 沟通 protocols between {software_components}.⸻ – Verify data exchange and synchronization across {list_of_subsystems}.⸻ – Ensure software interfaces comply with {integration_standards}.⸻⸻4. **General Integration Checks**⸻ – Conduct a system-wide test to identify potential interface issues.⸻ – Document and resolve any discrepancies found during integration.⸻ – Review and update the checklist based on integration outcomes.⸻⸻## EXECUTION⸻Use the provided input to generate the checklist, ensuring all aspects of mechanical, electrical, and software integration are covered comprehensively.[/prompt_formatter]
[prompt_formatter title=”Failure Mode and Effects Analysis (失效模式及影响分析) Starter” description=”Generates a preliminary FMEA table for a given mechanical system. This systematically identifies potential failure modes, their effects, and possible causes early in the design process.” temperature=”0.3″ thinking=”medium”]**TASK OVERVIEW**⸻Generate a preliminary FMEA table for a mechanical system to identify potential failure modes, their effects, and possible causes.⸻⸻**INPUT REQUIREMENTS**⸻1. Define the mechanical system: {mechanical_system_description}.⸻2. List key components: {list_of_components}.⸻3. Specify operating conditions: {operating_conditions}.⸻4. Identify known issues or historical failures: {known_issues}.⸻⸻**PROCESS**⸻1. Analyze each component in {list_of_components} to identify potential failure modes.⸻2. For each failure mode, determine the possible effects on the system and its operation.⸻3. Identify potential causes for each failure mode based on {operating_conditions} and {known_issues}.⸻4. Prioritize failure modes based on severity, occurrence, and detection likelihood.⸻⸻**OUTPUT FORMAT**⸻Generate a table with the following columns:⸻- Component⸻- Failure Mode⸻- Effect of Failure⸻- Cause of Failure⸻- Severity⸻- Occurrence⸻- Detection⸻- Risk Priority Number (RPN)⸻⸻**ADDITIONAL INSTRUCTIONS**⸻- Use industry standards for severity, occurrence, and detection ratings.⸻- Provide a summary of the top three critical failure modes with the highest RPN.⸻- Suggest mitigation strategies for the top critical failure modes.⸻⸻**END OF TASK**[/prompt_formatter]
[prompt_formatter title=”Risk Assessment Matrix” description=”Creates a risk assessment matrix (likelihood vs. severity) and populates it with potential hazards for a given mechanical system in a given industry and the number of desired steps. This provides a structured way to identify and prioritize safety risks.” temperature=”0.7″ thinking=”medium”]# RISK ASSESSMENT MATRIX CREATION⸻⸻## INPUT REQUIREMENTS⸻1. Define the mechanical system: {mechanical_system_description}⸻2. Specify the industry: {industry_type}⸻3. Determine the number of steps for the assessment: {number_of_steps}⸻⸻## TASK EXECUTION⸻1. **Identify Potential Hazards**⸻- List potential hazards associated with {mechanical_system_description} in {industry_type}.⸻2. **Assess Likelihood and Severity**⸻- For each hazard, evaluate the likelihood of occurrence and potential severity of impact.⸻3. **Create Risk Assessment Matrix**⸻- Construct a matrix with likelihood on one axis and severity on the other.⸻- Populate the matrix with identified hazards, categorizing them based on their likelihood and severity.⸻4. **Prioritize Risks**⸻- Rank the hazards in order of priority based on their position in the matrix.⸻5. **Develop Mitigation Strategies**⸻- Suggest strategies to mitigate high-priority risks.⸻⸻## OUTPUT⸻- Provide a structured risk assessment matrix with prioritized hazards and suggested mitigation strategies.⸻- Output format: $risk_assessment_matrix⸻⸻## ADDITIONAL INSTRUCTIONS⸻- Ensure clarity and precision in hazard identification and risk prioritization.⸻- Use industry-specific knowledge to enhance the accuracy of the assessment.[/prompt_formatter]
[prompt_formatter title=”Test Plan Outline for a Physical Prototype” description=”Generates a comprehensive test plan for validating a given physical prototype in a given industry and its main manufacturing process used. The output includes key performance indicators to measure, test procedures, required equipment, and data collection methods.” temperature=”0.7″ thinking=”high”]**TASK**⸻Generate a comprehensive test plan for validating a physical prototype.⸻⸻**INPUT REQUIREMENTS**⸻1. Industry: {industry_name}⸻2. Prototype Description: {prototype_description}⸻3. Main Manufacturing Process: {manufacturing_process}⸻⸻**OUTPUT**⸻Provide a detailed test plan including:⸻⸻1. **Key Performance Indicators (KPIs):**⸻- List the KPIs relevant to the prototype and industry.⸻- Explain why each 关键绩效指标 is critical for validation.⸻⸻2. **Test Procedures:**⸻- Outline step-by-step procedures for each test.⸻- Include conditions and parameters for testing.⸻⸻3. **Required Equipment:**⸻- List all necessary equipment and tools.⸻- Specify any special calibration or setup needed.⸻⸻4. **Data Collection Methods:**⸻- Describe methods for collecting and recording data.⸻- Include data analysis techniques to be used.⸻⸻**CONSIDERATIONS**⸻- Ensure alignment with industry standards and regulations.⸻- Address any safety and environmental concerns.⸻⸻**FORMAT**⸻Present the test plan in a structured format for easy reference and implementation.[/prompt_formatter]
Problem Solving and Troubleshooting
[prompt_formatter title=”Root Cause Analysis of Mechanical Failure” description=”Creates a fishbone (Ishikawa) diagram draft in Mermaid format populated with potential root causes for a specific mechanical failure. This provides a structured 框架 for effective troubleshooting and further investigations.” temperature=”0.5″ thinking=”medium”]**TASK**⸻Generate a fishbone (Ishikawa) diagram draft in Mermaid format to identify potential root causes for a specific mechanical failure.⸻⸻**INPUT REQUIREMENTS**⸻1. Specify the mechanical failure to be analyzed: {mechanical_failure_description}.⸻2. List the main categories of potential causes (e.g., Materials, Methods, Machines, Measurements, Environment, People): {cause_categories}.⸻3. Provide any known specific potential causes under each category: {specific_causes}.⸻⸻**OUTPUT FORMAT**⸻Generate the fishbone diagram in Mermaid format as follows:⸻“`mermaid⸻graph LR⸻A[Mechanical Failure: {mechanical_failure_description}] –> B1[{cause_category_1}]⸻A –> B2[{cause_category_2}]⸻A –> B3[{cause_category_3}]⸻…⸻B1 –> C1[{specific_cause_1}]⸻B1 –> C2[{specific_cause_2}]⸻B2 –> D1[{specific_cause_3}]⸻…⸻“`⸻⸻**INSTRUCTIONS**⸻1. Replace {mechanical_failure_description} with the specific mechanical failure being analyzed.⸻2. Replace {cause_categories} with the main categories of potential causes.⸻3. Replace {specific_causes} with any known specific potential causes under each category.⸻4. Ensure the diagram is logically structured and comprehensive for effective troubleshooting.⸻⸻**ADDITIONAL NOTES**⸻- The diagram should serve as a draft for further investigation and refinement.⸻- Consider consulting with team members or experts to validate and expand upon the potential causes listed.[/prompt_formatter]
[prompt_formatter title=”Vibration Troubleshooting Guide” description=”Creates a step-by-step guide for diagnosing and mitigating excessive vibration in a given specific machine. It covers potential sources like imbalance, misalignment, and resonance, along with common solutions for that machine.” temperature=”0.7″ thinking=”high”]# VIBRATION TROUBLESHOOTING GUIDE⸻⸻## INPUT REQUIREMENTS⸻1. Machine Type: {machine_type}⸻2. Machine Specifications: {machine_specifications}⸻3. Observed Vibration Symptoms: {vibration_symptoms}⸻4. Operating Conditions: {operating_conditions}⸻⸻## DIAGNOSTIC STEPS⸻1. **Initial Assessment**⸻ – Gather machine history and maintenance records.⸻ – Identify recent changes in operation or environment.⸻⸻2. **Vibration Analysis**⸻ – Measure vibration levels using appropriate sensors.⸻ – Compare with standard vibration thresholds for {machine_type}.⸻⸻3. **Identify Potential Sources**⸻ – Check for imbalance: Inspect rotating components for uneven mass distribution.⸻ – Check for misalignment: Verify alignment of shafts and couplings.⸻ – Check for resonance: Identify natural frequencies and compare with operating frequencies.⸻⸻## MITIGATION STRATEGIES⸻1. **Imbalance Solutions**⸻ – Perform dynamic balancing of rotating parts.⸻ – Replace or repair damaged components.⸻⸻2. **Misalignment Solutions**⸻ – Realign shafts and couplings using laser alignment tools.⸻ – Ensure proper installation procedures are followed.⸻⸻3. **Resonance Solutions**⸻ – Modify structural supports to alter natural frequencies.⸻ – Adjust operating speed to avoid resonance zones.⸻⸻## FINAL CHECKS⸻1. Re-measure vibration levels post-mitigation.⸻2. Compare with initial measurements to confirm reduction.⸻3. Document all findings and actions taken for future reference.⸻⸻## OUTPUT⸻- Provide a detailed report summarizing the diagnostic process and solutions implemented.⸻- Include recommendations for ongoing monitoring and maintenance.⸻[/prompt_formatter]
Project Management and Communication
[prompt_formatter title=”Project Timeline and Milestone Suggestions” description=”Creates a high-level project timeline with key milestones for a typical mechanical design project of a given industry. This assists in project planning, resource allocation, and progress tracking.” temperature=”0.7″ thinking=”medium”]**TASK**⸻Generate a high-level project timeline with key milestones for a mechanical design project in the {industry} industry.⸻⸻**INPUT REQUIREMENTS**⸻1. Industry: Specify the industry for the mechanical design project, e.g., automotive, aerospace, consumer electronics.⸻2. Project Duration: Define the total expected duration of the project in weeks or months.⸻3. Key Phases: List the key phases of the project, such as concept development, design, prototyping, testing, and production.⸻4. Milestone Criteria: Define criteria for key milestones, such as design approval, prototype completion, testing results, and production readiness.⸻⸻**OUTPUT**⸻1. A detailed project timeline with start and end dates for each phase.⸻2. Key milestones with estimated completion dates and criteria.⸻3. Suggestions for resource allocation and potential bottlenecks.⸻⸻**INSTRUCTIONS**⸻1. Analyze the provided industry and project duration to tailor the timeline.⸻2. Break down the project into specified phases and allocate time based on industry standards.⸻3. Identify key milestones within each phase and suggest realistic completion dates.⸻4. Provide recommendations for resource allocation and highlight potential bottlenecks or risks.⸻⸻**EXAMPLE**⸻Industry: Automotive⸻Project Duration: 12 months⸻Key Phases: Concept Development, Design, Prototyping, Testing, Production⸻Milestone Criteria: Design Approval, Prototype Completion, Testing Results, Production Readiness⸻⸻**OUTPUT FORMAT**⸻- Project Timeline: $projecttimeline⸻- Key Milestones: $keymilestones⸻- Resource Allocation Suggestions: $resourceallocation⸻- Potential Bottlenecks: $potentialbottlenecks[/prompt_formatter]
[prompt_formatter title=”Stakeholder Communication Plan” description=”Develops a communication plan for an engineering project with a given industry and specific challenges, identifying key stakeholders, their interests, and the appropriate communication methods. This ensures information flows effectively throughout the project lifecycle.” temperature=”0.7″ thinking=”medium”]# STAKEHOLDER COMMUNICATION PLAN⸻⸻## INPUT REQUIREMENTS⸻- **Industry**: Specify the industry related to the engineering project (e.g., automotive, aerospace, construction).⸻- **Project Challenges**: Describe the specific challenges faced in the project.⸻- **Project Lifecycle Stages**: List the stages of the project lifecycle (e.g., initiation, planning, execution, closure).⸻⸻## TASKS⸻1. **Identify Key Stakeholders**⸻ – List all potential stakeholders involved in the project.⸻ – Determine their roles and responsibilities.⸻⸻2. **Analyze Stakeholder Interests**⸻ – For each stakeholder, identify their primary interests and concerns.⸻ – Assess the impact of the project on each stakeholder.⸻⸻3. **Determine Communication Methods**⸻ – Select appropriate communication methods for each stakeholder (e.g., meetings, reports, emails).⸻ – Define the frequency and format of communication for each stakeholder.⸻⸻4. **Develop Communication Plan**⸻ – Create a detailed communication plan outlining the flow of information throughout the project lifecycle.⸻ – Ensure the plan addresses the specific challenges identified.⸻⸻## OUTPUT⸻- **Stakeholder List**: $stakeholderlist⸻- **Stakeholder Interests and Impact**: $stakeholderinterests⸻- **Communication Methods**: $communicationmethods⸻- **Comprehensive Communication Plan**: $communicationplan⸻⸻## EXECUTION⸻Use the provided inputs to generate a comprehensive stakeholder communication plan that ensures effective information flow and addresses project-specific challenges.[/prompt_formatter]
Learning and Skill Development
In case you could not find these learning resources already on innovation.world (use the search feature or ask us in the contact form).
[prompt_formatter title=”Explain a Complex Engineering Concept Simply” description=”Explains a complex mechanical engineering topic (e.g., PID controllers, Navier-Stokes equations) in simple terms using analogies.” temperature=”0.7″ thinking=”medium”]## TASK⸻Explain the complex mechanical engineering concept of {concept_name} in simple terms using analogies.⸻⸻## INPUTS⸻1. Concept Name: {concept_name}⸻2. Key Elements: List the key elements or components of the concept.⸻3. Function: Describe the primary function or purpose of the concept.⸻4. Context: Provide a brief context or scenario where this concept is applied.⸻⸻## OUTPUT⸻1. Simplified Explanation: Provide a simple explanation of the concept using relatable analogies.⸻2. Key Elements Description: Describe each key element in simple terms.⸻3. Function Analogy: Use an analogy to explain the primary function.⸻4. Contextual Example: Offer a simple example or scenario illustrating the concept in action.⸻⸻## INSTRUCTIONS⸻- Use clear and concise language.⸻- Avoid technical jargon.⸻- Ensure analogies are relatable to a general audience.⸻- Maintain accuracy while simplifying complex ideas.⸻⸻## EXAMPLE⸻- Concept Name: PID Controller⸻- Key Elements: Proportional, Integral, Derivative⸻- Function: Maintain desired output by adjusting control inputs.⸻- Context: Used in temperature control systems.⸻⸻### Simplified Explanation⸻A PID controller is like a car’s cruise control system. It adjusts the throttle to maintain a set speed, just as a PID adjusts inputs to maintain a desired output.⸻⸻### Key Elements Description⸻- Proportional: Like pressing the gas pedal harder when you want to speed up.⸻- Integral: Like remembering how much you’ve slowed down over time and adjusting accordingly.⸻- Derivative: Like anticipating how fast you’re approaching a stop sign and easing off the gas.⸻⸻### Function Analogy⸻The PID controller is the driver who keeps the car at a steady speed despite hills and curves.⸻⸻### Contextual Example⸻Imagine using a PID controller in a heating system to keep your home at a cozy temperature, adjusting the heat based on how cold it gets outside.[/prompt_formatter]
[prompt_formatter title=”Generate Practice Problems for a Specific Topic” description=”Creates a set of practice problems, including detailed solutions, for a specific mechanical engineering subject (e.g., thermodynamics, machine design).” temperature=”0.7″ thinking=”medium”]## TASK OVERVIEW⸻Generate a set of practice problems with detailed solutions for a specific mechanical engineering subject to aid in skill sharpening.⸻⸻## INPUT REQUIREMENTS⸻1. Specify the mechanical engineering subject: {subject} (e.g., thermodynamics, machine design).⸻2. Define the number of practice problems required: {number_of_problems}.⸻3. Indicate the difficulty level: {difficulty_level} (e.g., beginner, intermediate, advanced).⸻⸻## OUTPUT STRUCTURE⸻1. **Problem Set**: Generate {number_of_problems} practice problems related to {subject}.⸻2. **Solutions**: Provide detailed solutions for each problem, including step-by-step calculations and explanations.⸻3. **Key Concepts**: Highlight the key concepts and principles involved in solving each problem.⸻⸻## EXECUTION INSTRUCTIONS⸻- Use clear and concise language suitable for expert-level mechanical engineers.⸻- Ensure problems cover a range of scenarios within the specified subject.⸻- Solutions should be detailed enough to facilitate understanding and learning.⸻- Include any necessary diagrams or illustrations to support problem-solving.⸻⸻## OUTPUT FORMAT⸻- Present each problem followed by its solution.⸻- Use bullet points or numbered lists for clarity.⸻- Ensure all mathematical expressions are clearly formatted.⸻⸻## ADDITIONAL NOTES⸻- Consider incorporating real-world applications to enhance relevance.⸻- Ensure accuracy and precision in all calculations and explanations.[/prompt_formatter]
