Grain Watch MCP Server for VS Code Copilot 12 tools — connect in under 2 minutes
GitHub Copilot in VS Code is the most widely adopted AI coding assistant, embedded directly into the world's most popular code editor. With MCP support in Agent mode, Copilot can access external data and APIs to generate context-aware code grounded in real-time information.
ASK AI ABOUT THIS MCP SERVER
Vinkius supports streamable HTTP and SSE.
Vinkius Desktop App
The modern way to manage MCP Servers — no config files, no terminal commands. Install Grain Watch and 2,500+ MCP Servers from a single visual interface.
{
"mcpServers": {
"grain-watch": {
"url": "https://edge.vinkius.com/[YOUR_TOKEN_HERE]/mcp"
}
}
}
* Every MCP server runs on Vinkius-managed infrastructure inside AWS - a purpose-built runtime with per-request V8 isolates, Ed25519 signed audit chains, and sub-40ms cold starts optimized for native MCP execution. See our infrastructure
About Grain Watch MCP Server
Connect your Grain Watch Silo Temperature Monitoring API to any AI agent and take full control of real-time temperature tracking, humidity monitoring, hot spot detection, and AI-powered spoilage risk assessment through natural conversation.
GitHub Copilot Agent mode brings Grain Watch data directly into your VS Code workflow. With a project-scoped config, the entire team shares access to 12 tools. Copilot queries live data, generates typed code, and writes tests from actual API responses, all without leaving the editor.
What you can do
- Silo Management — List and manage all temperature-monitored silos with grain types and sensor status
- Real-Time Temperature — Get current temperature readings from all sensors throughout the grain mass
- Humidity Monitoring — Track relative humidity levels for condensation risk assessment
- Temperature History — Analyze historical temperature trends to detect developing hot spots
- Humidity History — Monitor humidity patterns for moisture migration and condensation detection
- Sensor Mapping — View complete sensor layout with positions, depths, and zones
- Hot Spot Alerts — Receive automatic alerts when localized heating indicates potential spoilage
- Spoilage Risk — Get AI-powered risk assessments combining temperature, humidity, and grain type
- Alert Management — Monitor all active alerts for temperature, humidity, and sensor issues
- Sensor Health — Track sensor battery levels, communication status, and operational health
- Facility Overview — Get comprehensive facility-wide temperature summaries for executive reporting
The Grain Watch MCP Server exposes 12 tools through the Vinkius. Connect it to VS Code Copilot in under two minutes — no API keys to rotate, no infrastructure to provision, no vendor lock-in. Your configuration, your data, your control.
How to Connect Grain Watch to VS Code Copilot via MCP
Follow these steps to integrate the Grain Watch MCP Server with VS Code Copilot.
Create MCP config
Create a .vscode/mcp.json file in your project root
Add the server config
Paste the JSON configuration above
Enable Agent mode
Open GitHub Copilot Chat and switch to Agent mode using the dropdown
Start using Grain Watch
Ask Copilot: "Using Grain Watch, help me...". 12 tools available
Why Use VS Code Copilot with the Grain Watch MCP Server
GitHub Copilot for Visual Studio Code provides unique advantages when paired with Grain Watch through the Model Context Protocol.
VS Code is used by over 70% of developers. adding MCP tools to Copilot means your team can leverage external data without leaving their primary editor
Project-scoped MCP configs (`.vscode/mcp.json`) let you commit server configurations to your repository, ensuring the entire team shares the same tool access
Copilot's Agent mode integrates MCP tools seamlessly with file editing, terminal commands, and workspace search in a single agentic loop
GitHub's enterprise compliance and audit features extend to MCP tool usage, providing visibility into how AI interacts with external services
Grain Watch + VS Code Copilot Use Cases
Practical scenarios where VS Code Copilot combined with the Grain Watch MCP Server delivers measurable value.
Live API integration: Copilot can query an MCP server, inspect the response schema, and generate typed API client code in the same step
DevSecOps workflows: security teams can give developers access to domain intelligence tools directly in their editor for real-time vulnerability assessment during code review
Data pipeline development: Copilot fetches sample data via MCP and generates transformation scripts, validators, and test fixtures from actual API responses
Documentation generation: Copilot queries available tools and auto-generates README sections, API reference docs, and usage examples
Grain Watch MCP Tools for VS Code Copilot (12)
These 12 tools become available when you connect Grain Watch to VS Code Copilot via MCP:
get_alerts
Returns alert type, severity (critical, warning, info), affected silo, timestamp, and recommended actions. Essential for comprehensive operational monitoring, issue detection, and management response. AI agents should use this when users ask "show me all active alerts", "what warnings have been triggered for silo 3", or need alert data for operational monitoring. Optional silo_id filters alerts for a specific silo. Get all active alerts for temperature, humidity, and sensor issues
get_current_humidity
Returns relative humidity (%) values from multiple sensor positions. High humidity combined with temperature indicates condensation risk and potential spoilage conditions. Essential for moisture migration detection, condensation risk assessment, and grain quality preservation. AI agents should reference this when users ask "what is the humidity level in silo 3", "show me humidity readings for silo 5", or need current humidity data for storage condition assessment. Get current humidity readings from sensors in a grain silo
get_current_temperature
Returns temperature values (Celsius) from multiple sensor positions throughout the grain mass including top, middle, bottom, and center zones. Essential for real-time grain condition monitoring, hot spot detection, and spoilage prevention. AI agents should use this when users ask "what is the current temperature in silo 2", "show me all temperature readings for silo 4", or need immediate grain temperature data for storage management decisions. Get current temperature readings from all sensors in a grain silo
get_facility_overview
Essential for executive reporting, facility-wide condition assessment, and strategic storage management. AI agents should use this when users ask "give me an overview of all my silos", "what is the overall temperature status across the facility", or need facility-level summaries for management reporting. Get comprehensive overview of all monitored silos and their temperature status
get_hotspot_alerts
Returns alert severity (critical, warning), affected silo, sensor zone location, temperature differential, detection timestamp, and recommended actions. Hot spots are early indicators of grain quality issues that require immediate attention. Essential for proactive grain management, spoilage prevention, and quality preservation. AI agents should use this when users ask "are there any hot spots detected", "show hotspot alerts for silo 3", or need early warning indicators of grain spoilage. Optional silo_id filters alerts for a specific silo. Get active hot spot detection alerts for all silos or a specific silo
get_humidity_history
Humidity patterns over time help identify moisture migration, condensation events, and drying effectiveness. Returns time-series humidity data (%) with timestamps from multiple sensor positions. Essential for moisture migration analysis, condensation detection, and storage safety monitoring. AI agents should reference this when users ask "show me humidity trends for silo 1", "has humidity been stable in silo 2", or need historical humidity data for storage management. Get historical humidity readings to track moisture migration patterns
get_sensor_health
Returns sensor IDs, positions, communication status, last reading time, battery levels (for wireless sensors), and operational status (active, offline, fault, needs calibration). Essential for sensor network maintenance, data continuity assurance, and monitoring system reliability. AI agents should reference this when users ask "are all sensors working in silo 5", "which sensors have gone offline", or need sensor health data for system administration. Get health status of all temperature and humidity sensors in a silo
get_sensor_map
Returns sensor IDs, physical locations (top/middle/bottom, center/perimeter), installation depths, and current operational status. Essential for understanding temperature distribution across the grain mass, identifying which sensor corresponds to which physical location, and troubleshooting sensor issues. AI agents should use this when users ask "show me the sensor layout for silo 4", "where are the sensors positioned in silo 6", or need sensor positioning data for temperature analysis interpretation. Get the layout and positions of all temperature sensors in a silo
get_silo_details
Essential for understanding silo context before analyzing temperature data, planning aeration strategies, or generating storage condition reports. AI agents should reference this when users ask "tell me about silo 3", "what grain is stored in silo 5 and how many sensors does it have", or need detailed silo metadata for informed analysis. Get detailed information about a specific grain silo
get_silos
Returns silo IDs, names, locations, grain types, current temperature status, and monitoring health. Essential for facility overview, silo inventory management, and selecting specific silos for detailed temperature analysis. AI agents should use this when users ask "show me all my monitored silos", "list temperature-monitored storage units", or need to identify available silos before querying temperature readings or alerts. List all grain silos monitored by Grain Watch
get_spoilage_risk
Returns risk level (low, moderate, high, critical), contributing factors, predicted days until spoilage if conditions persist, and recommended preventive actions. Essential for proactive grain management, early intervention planning, and quality preservation. AI agents should use this when users ask "what is the spoilage risk for silo 3", "is silo 5 at risk of spoilage", or need AI-driven risk assessments for storage management decisions. Get AI-powered spoilage risk assessment for a specific silo
get_temperature_history
Temperature trends over time are critical for identifying developing hot spots, spoilage heating, or effective cooling from aeration. Returns time-series temperature data (Celsius) with timestamps from multiple sensor zones. Essential for hot spot detection, spoilage heating identification, aeration effectiveness evaluation, and grain quality preservation. AI agents should use this when users ask "show me temperature trends for silo 3 over the past 30 days", "has silo 5 been heating up", or need historical temperature data for storage condition analysis. Optional days parameter controls lookback period. Get historical temperature readings to detect trends and hot spot development
Example Prompts for Grain Watch in VS Code Copilot
Ready-to-use prompts you can give your VS Code Copilot agent to start working with Grain Watch immediately.
"Show me the current temperature readings for silo 3."
"Check for any hot spot alerts across my facility."
"Give me a facility-wide overview of all silo temperatures and any active alerts."
Troubleshooting Grain Watch MCP Server with VS Code Copilot
Common issues when connecting Grain Watch to VS Code Copilot through the Vinkius, and how to resolve them.
MCP tools not available
Grain Watch + VS Code Copilot FAQ
Common questions about integrating Grain Watch MCP Server with VS Code Copilot.
Which VS Code version supports MCP?
How do I switch to Agent mode?
Can I restrict which MCP tools Copilot can access?
Does MCP work in VS Code Remote or Codespaces?
.vscode/mcp.json work in Remote SSH, WSL, and GitHub Codespaces environments. The MCP connection is established from the remote host, so ensure the server URL is accessible from that environment.Connect Grain Watch with your favorite client
Step-by-step setup guides for every MCP-compatible client and framework:
Anthropic's native desktop app for Claude with built-in MCP support.
AI-first code editor with integrated LLM-powered coding assistance.
GitHub Copilot in VS Code with Agent mode and MCP support.
Purpose-built IDE for agentic AI coding workflows.
Autonomous AI coding agent that runs inside VS Code.
Anthropic's agentic CLI for terminal-first development.
Python SDK for building production-grade OpenAI agent workflows.
Google's framework for building production AI agents.
Type-safe agent development for Python with first-class MCP support.
TypeScript toolkit for building AI-powered web applications.
TypeScript-native agent framework for modern web stacks.
Python framework for orchestrating collaborative AI agent crews.
Leading Python framework for composable LLM applications.
Data-aware AI agent framework for structured and unstructured sources.
Microsoft's framework for multi-agent collaborative conversations.
Connect Grain Watch to VS Code Copilot
Get your token, paste the configuration, and start using 12 tools in under 2 minutes. No API key management needed.