Design Consulting

1.1. Laboratory Site Selection Consulting

Location Division

Architectural Factors

Fire Protection Factors

Prospective Factors

1.2. Overall GMP Consulting Services

Legal Compliance Consulting and Training

GMP Design Consulting and Training

Quality System Consulting and Training

Validation Consulting and Training

1.3. Pharmaceutical Quality System (PQS) Consulting Services

GMP Design Review

Development/Technology Transfer

Pharmaceutical Quality System Documentation

Mock Inspections

Inspection Support

1.4. Validation Consulting Services

Project Quality Plan

Quality Risk Management Plan

Validation Master Plan

URS Review and Preparation

Design Review

HVAC System Validation

Clean Piping System Certification

Laboratory Design Specialties:

Electrical Design

HVAC Design

Water Supply and Plumbing Design

Gas System Design

Decoration Design

Fire Protection Design

Laboratory Design

Interior Design: Design laboratory interiors, including the selection of wall, floor, and ceiling finish materials and construction process design. Consideration should be given to materials' corrosion resistance, cleanability, and fire resistance to meet laboratory operational requirements and safety standards. The layout and design of laboratory furniture, such as lab benches, fume hoods, and medicine cabinets, should be designed. Furniture should be rationally arranged according to experimental procedures and operating habits to enhance laboratory efficiency and comfort. Interior color matching and signage should be designed to create a comfortable and safe laboratory environment and facilitate identification and operation.

Electrical Design: Design power systems, including calculating the laboratory's electrical load, selecting appropriate transformers, distribution boxes, and other equipment, and designing power supply lines to ensure a stable and reliable power supply for various laboratory instruments, lighting, and electrical outlets. Lighting systems should also be designed, selecting appropriate lamps and lighting methods based on the functional requirements of different experimental areas to meet the illumination requirements for experimental operations, while also considering energy efficiency and uniform lighting. Lightning protection and grounding systems should also be designed to ensure the safety of laboratory equipment and personnel.

Water Supply and Drainage Design: Design the laboratory's water supply system. Based on the water requirements of laboratory instruments and equipment, determine the water source connection method and pipe diameter, ensuring that the water quality, quantity, and pressure meet the requirements. Furthermore, design the drainage system, including the separate collection and discharge of wastewater. Corrosive, toxic, and hazardous wastewater must be treated specifically to meet environmental standards before being discharged into the municipal sewage network.

HVAC Design: Design the ventilation system. Based on the laboratory type and experimental content, determine ventilation methods such as localized ventilation and general ventilation. Select appropriate ventilation equipment, such as fume hoods and exhaust fans, to effectively remove harmful gases, vapors, and dust generated during the experiment, ensuring that laboratory air quality meets hygienic standards. Air conditioning systems are also designed to control laboratory temperature and humidity, meet the environmental requirements of laboratory instruments and equipment, and consider energy efficiency and comfort. For laboratories with special requirements, such as cleanroom labs, air purification systems are also required to provide a clean air environment.

Gas Flow Design: Design gas flow systems for laboratories that use various gases, such as chemical labs and analytical testing labs. This includes the selection and placement of gas sources, such as gas cylinder rooms and centralized gas supply stations; designing gas pipelines, selecting appropriate pipe materials and connection methods based on the properties and requirements of different gases to ensure safe and stable gas delivery; and installing gas control and monitoring equipment, such as pressure reducing valves, flow meters, and gas alarms, to ensure proper and safe gas use.

Fire Protection Design: Designs a fire protection system based on the laboratory's fire hazard classification. This includes fire hydrant systems, automatic sprinkler systems, and gas fire extinguishing systems. Firefighting equipment and equipment, such as fire extinguishers and fire hydrant boxes, are strategically located to ensure timely and effective firefighting and rescue efforts in the event of a fire. Furthermore, a fire alarm system is designed, including the installation of fire detectors and alarms, to ensure early detection and warning of fires, ensuring the safety of personnel and equipment.

Environmental Design: Designs the treatment and disposal of waste gas, wastewater, waste residue, and other pollutants generated by the laboratory. Use appropriate waste gas treatment equipment and processes, such as activated carbon adsorption and catalytic oxidation, to purify harmful waste gases so that they meet emission standards; design wastewater treatment facilities and processes to treat wastewater containing pollutants such as heavy metals and organic matter to meet environmental emission standards; for solid waste generated during the experiment, design classified collection and storage facilities, and properly handle or dispose of it in accordance with relevant regulations.

Laboratory Construction

Project Initiation Phase: Define the experiment type, calculate the number of participants, frequency, and instrument types, and divide the laboratory into functional areas, such as sample processing and analysis and testing areas. Also, confirm the budget and timeline. It is recommended to engage an experienced laboratory design company or equipment manufacturer for advance technical consultation.

Design Planning Phase: Develop a spatial layout that includes functional area divisions, equipment and furniture placement, and system diagrams for ventilation, plumbing, and electrical wiring. If possible, create a BIM model or 3D rendering to anticipate space issues and develop a precise construction drawing. The focus is on optimizing movement, complying with safety regulations, and ensuring complete functionality.

Equipment and Furniture Selection Phase: Select laboratory furniture, such as workstations and fume hoods, based on the experiment type. Also determine laboratory equipment, such as ventilation systems and eyewash stations. When selecting, consider the product's environmental and certification requirements, as well as indicators such as load-bearing capacity and corrosion resistance.

Construction and installation phase: Carry out civil construction, including partition walls and floor treatment, simultaneously promote the installation of water, electricity, gas, ventilation and other systems, have professional manufacturers customize and install furniture according to drawings, complete the commissioning of equipment on site, such as the commissioning and acceptance of fume hood wind speed and pipeline sealing. Regular on-site coordination meetings are recommended during this phase to ensure safe and orderly multi-disciplinary operations.

Acceptance, delivery and after-sales stage: Party A, the construction party and the design party jointly participate in the completion acceptance. If necessary, third-party inspections such as ventilation speed and air tightness will be carried out, and the completion drawings, equipment manuals and other materials will be archived. Furthermore, high-quality manufacturers generally offer a one- to five-year warranty and regular inspections.

Laboratory Equipment

Our main business is providing one-stop controlled environment comprehensive solutions, encompassing consulting, design, construction, validation, and after-sales service, for the construction of laboratories, pilot plants, and GMP workshops for industries such as biopharmaceuticals, cell-based drugs, mRNA vaccines, antibody drugs, and sterile preparations.

The company holds Class-III qualifications for professional contracting of building mechanical and electrical installation engineering, Class-II qualifications for professional contracting of building decoration and renovation engineering, Class-II qualifications for professional contracting of fire protection facilities engineering, Class-III qualifications for professional contracting of environmental protection engineering, and Class-B qualifications for specialized design of building decoration engineering. Our branch holds Class-A qualifications for design in the chemical, petrochemical, and pharmaceutical industries (chemical APIs and pharmaceutical preparations).

Testing and Validation

ISO 17025 Standard 1: The full name is "General Requirements for the Competence of Testing and Calibration Laboratories," developed by the International Organization for Standardization (ISO/CASCO). This standard specifies general requirements for laboratory management and technical competence, including definitions, organization and management, quality systems, audits and reviews, personnel, facilities and environment, equipment and reference materials, traceability and calibration, calibration and test methods, sample management, records, certificates, and reports. Laboratories accredited to ISO 17025 demonstrate their technical competence to perform calibration/testing in accordance with relevant international standards, and their reports are recognized by multiple organizations worldwide.

GB/T 27025 Standard 2: Equivalent to ISO 17025, it is my country's national standard for general requirements for the competence of testing and calibration laboratories. It provides unified management and technical specifications for Chinese laboratories, enabling them to ensure the accuracy, reliability, and validity of their testing and calibration results. This helps improve management and technical capabilities, enhance market competitiveness, and promote international trade and technological exchange.

Industry-Specific Standards: Different industries have their own laboratory testing and validation standards. For example, in the medical field, there is CNAS-CL02 "Criteria for Accreditation of Quality and Capabilities of Medical Laboratories", which puts forward specific requirements for the management and technical capabilities of medical laboratories; in the agricultural field, SC/T 7030-2025 "Technical Specifications for Proficiency Verification of Aquatic Animal Pathogen Detection Laboratories" stipulates the technical requirements for proficiency verification of aquatic animal pathogen detection laboratories; in the civil aviation field, MH/T 6096-2013 "Proficiency Verification Procedures for Civil Aviation Fuel Testing Laboratories" is applicable to the proficiency verification of civil aviation fuel testing laboratories.

After-sales Service

Timeliness

24-hour after-sales hotline

Regular follow-up calls

Critical faults resolved within 2 hours

Professionalism

Clear technical solutions

Recorded technical briefing numbers

Regular training for after-sales staff

Regular follow-up visits by project managers

Reasonableness

Clear accountability for faults

Timely resolution of quality issues

Transparent pricing for consumables

Secondary training for operational issues

Traceability

After-sales service follow-up

Service clock-in/check-in records

Resolution effectiveness linked to performance