The Ultimate Guide to Grossing Station Selection

How to Precisely Choose Materials and Worktop Structures Based on Application Scenarios

Introduction: Why “One-Size-Fits-All” Grossing Stations Are Wasting Your Resources

In laboratories, pathology departments, and industrial testing environments, the grossing station is often one of the most critical—yet most overlooked—elements of the workflow. Many institutions continue to use “general-purpose” grossing stations without realizing that inappropriate choices can quietly increase cross-contamination risks, reduce operational efficiency, and even compromise sample quality.

This guide provides an in-depth analysis of how to select the most suitable grossing station materials and structural designs based on specific application scenarios, helping you make precise investments and significantly improve overall workflow performance.

1. Understanding the Core Relationship: How Application Scenarios Define Material and Structural Requirements

1.1 A Three-Dimensional Analysis of Application Scenarios

• Sample type: biological tissues, industrial materials, chemical substances, etc.
• Operational workflow: cutting, dissection, sampling, testing, and related procedures
• Environmental requirements: cleanliness level, temperature and humidity control, corrosive atmospheres

1.2 The Synergy Between Material and Structure

Materials determine durability and safety, while structural design directly affects efficiency and ergonomics. Only when both are precisely matched to the application scenario can optimal performance be achieved.

2. Comprehensive Material Selection Guide: Precise Matching from Laboratories to Industrial Settings

2.1 Stainless Steel: The Preferred Choice for Medical Institutions

Applicable scenarios:

• Pathology tissue grossing
• Microbiology laboratories
• Environments requiring frequent disinfection

Advantages:

• Excellent corrosion resistance, tolerant to repeated cleaning with alcohol and disinfectants
• Non-porous surfaces that effectively prevent bacterial retention
• High load-bearing capacity, suitable for heavy instruments
• Easy to clean and compliant with medical cleanliness standards

Selection recommendation:
Use 304 or 316 medical-grade stainless steel with a thickness of no less than 1.2 mm.

2.2 Solid Phenolic Board: A Protective Shield for Chemical Laboratories

Applicable scenarios:

• Chemical laboratories
• Environments involving acids, alkalis, and solvents
• Teaching anatomy laboratories

Advantages:

• Outstanding chemical corrosion resistance
• High impact resistance and durability
• Heat resistant and suitable for contact with hot instruments
• Available in multiple colors for functional zoning

Selection recommendation:
Choose panels with a thickness of 12.7 mm or greater, with properly sealed edges.

2.3 Polymer Materials (PP): A Solution for Special Environments

Applicable scenarios:

• High-cleanliness biological laboratories
• Radioactive or special contaminant handling areas
• Humid or dusty industrial environments

Advantages:

• One-piece molded structure with no seams, preventing leakage
• Excellent resistance to strong acids and alkalis
• Lightweight, durable, and electrically insulating
• Customizable colors and structural designs

2.4 Epoxy Resin Worktops: A Reliable Backbone for Heavy-Duty Industrial Use

Applicable scenarios:

• Industrial testing laboratories
• Heavy machinery maintenance areas
• High-temperature or high-wear environments

Advantages:

• Extremely high abrasion and impact resistance
• Heat resistance exceeding 300°C
• Exceptional load-bearing capacity
• Long service life with low maintenance costs

3. Worktop Structural Design: Key Details That Drive Efficiency

3.1 Drainage System Design: The Art of Wet–Dry Separation

Integrated sink design

• Ideal for pathology and anatomy laboratories
• Allows liquids to flow directly into treatment systems
• Reduces contamination risks during sample transfer

Raised-edge spill containment

• Suitable for chemical laboratories
• Prevents liquid overflow and protects operators
• Optional circular drainage channels available

Dry worktop design

• Designed for electronics testing and precision instrument work
• No drainage system to ensure a completely dry surface
• Optional anti-static surface treatment

3.2 Height and Tiering: Practical Ergonomics in Action

Fixed-height standard stations

• Suitable for predominantly standing operations
• Recommended height: 90–95 cm (for Asian populations)

Height-adjustable designs

• Ideal for shared use or specialized operational needs
• Available with electric or manual adjustment

Multi-tier structural design

• Upper operational area with lower storage space
• Ideal for space-limited environments
• Can improve efficiency by more than 30%

3.3 Integrated Functional Modules: The Future of Smart Laboratories

Built-in lighting systems

• Surgical-grade shadow-free LED lighting
• Adjustable color temperature and brightness

Integrated ventilation

• Local exhaust systems for effective control of hazardous fumes
• Low-noise design to maintain a comfortable working environment

Intelligent temperature control modules

• Maintain samples within optimal temperature ranges
• Suitable for temperature-sensitive operations

4. Scenario-Based Selection Solutions: Four Typical Application Cases

4.1 Hospital Pathology Department

Core requirements: contamination prevention, easy disinfection, efficient drainage

Recommended configuration:

• Material: 316L medical-grade stainless steel
• Structure: integrated stainless steel sink with background lighting
• Size: minimum 2.5 meters per single-operator workstation
• Additional features: integrated temporary specimen refrigeration

4.2 Biosafety Laboratories

Core requirements: airtightness, disinfectant resistance, airflow control

Recommended configuration:

• Material: one-piece molded PP
• Structure: seamless design with raised spill edges
• Ventilation: integrated exhaust system with HEPA filtration
• Safety: emergency eyewash and rinse systems

4.3 Industrial Testing Laboratories

Core requirements: wear resistance, load-bearing capacity, multifunctionality

Recommended configuration:

• Material: 20 mm epoxy resin worktop
• Structure: heavy-duty support with vibration-damping design
• Modules: replaceable tool integration modules
• Expansion: reserved interfaces for instruments and cable routing

4.4 Teaching Laboratories

Core requirements: safety, durability, cost efficiency

Recommended configuration:

• Material: ceramic or solid phenolic board
• Structure: fixed height with impact-resistant edges
• Layout: group-based island-style configuration
• Safety: emergency power cut-off and rinse systems

5. Selection Decision Flow: Five Steps to the Optimal Solution

1. Scenario analysis → Identify primary operations and environmental requirements
2. Initial material selection → Screen based on chemical exposure and cleanliness needs
3. Structural matching → Design drainage, storage, and layout according to workflow
4. Size planning → Determine dimensions based on space and number of users
5. Budget optimization → Achieve the best balance between requirements and cost

6. Maintenance and Upgrading: Practical Tips to Extend Service Life

6.1 Routine Maintenance Essentials

• Use appropriate cleaning agents for different materials
• Regularly inspect drainage system flow
• Avoid overloading and improper use

6.2 Upgrade and Retrofit Opportunities

• Modular designs that simplify future upgrades
• Functional retrofitting of existing grossing stations
• Pathways toward smart and automated upgrades

Conclusion: Precise Selection Creates Long-Term Value

Choosing the right grossing station is not simply an equipment purchase—it is a strategic investment in workflow efficiency, personnel safety, and sample integrity. By thoroughly analyzing application scenarios and precisely matching materials with structural designs, you gain more than a workbench; you gain a key tool for optimizing your entire operational process.

Remember the three golden rules:

1. Scenario determines material – let environmental needs guide material choice
2. Workflow determines structure – let working habits shape design details
3. The future determines flexibility – leave room for growth and change

Share your application scenario in the comments to receive personalized selection advice. If you found this guide helpful, please share it with others who may benefit—together, we can raise industry standards and improve operational efficiency.