Jining Public Health Medical Center

Total duration: 90 days

The Jining Public Health Medical Center—formerly known as the Jining Infectious Disease Hospital—was established in 1953. Steeped in a rich historical legacy, it serves as a pivotal node within the healthcare system of southwestern Shandong. The Center is dedicated to the comprehensive development of internal medicine, surgery, obstetrics, and pediatrics; it integrates medical treatment, disease prevention, health promotion, scientific research, and medical education into a single entity. Recognized as a modern tertiary-level hospital, it functions as a highly efficient platform that seamlessly combines teaching, research, and clinical practice.

Located in Rencheng District, Jining City, Shandong Province, this project spans an area of ​​238 mu and features a total planned floor area of ​​approximately 170,000 square meters, with a projected capacity of 900 beds. It not only underscores a lofty ambition to serve public health but also reflects a forward-looking anticipation of future growth in healthcare demand.

The project was scheduled for a duration of 90 days. Despite the tight timeline and arduous working conditions, the project team upheld a spirit of exceptional craftsmanship, tirelessly refining the design scheme and driving the construction forward day and night. They strove to perfect every minute detail, aiming to deliver a final outcome that would surpass all expectations.
Under the pressure of a tight schedule, the team remained unyielding in their dedication to meticulously refining and iteratively innovating upon the design drawings. This process not only enhanced the precision of the blueprints but also propelled the evolution of their design philosophy and the continuous optimization of the overall solution—constantly striving for a perfect equilibrium between functionality, resource efficiency, and environmental sustainability. Through intensive workshops, rigorous technical validation, and on-site surveys, the team precisely identified the optimal strategies. This approach ensured the accuracy and practical applicability of the design implementation, effectively mitigated construction variables, and accelerated the project's

The scope of this project focuses specifically on Package 3 of the specialized medical engineering works—a critical component tasked with realizing the overall functionality and comfort of the entire development. Every stage of the process is meticulously crafted with the aim of creating a healing environment that not only meets the rigorous requirements of a medical setting but also embodies a spirit of humanistic care. The precise layout of the HVAC system ensures constant temperature and humidity year-round, providing an optimal indoor environment for both medical staff and patients. The meticulous design and implementation of both high-voltage power and low-voltage intelligent systems serve as the vital lifelines for information and electricity, underpinning the hospital's efficient operations. The scientific planning of the water supply and drainage systems guarantees water safety and the efficient utilization of resources, while the rigorous installation and commissioning of the medical gas supply systems provide indispensable support for various laboratory research activities.
This project encompasses a comprehensive, end-to-end service chain—ranging from detailed design development, material and equipment procurement, construction and installation, and system commissioning, through to final acceptance and subsequent warranty maintenance. This holistic approach ensures that every aspect of the work adheres to the highest industry standards, thereby providing the medical institution with a safe, efficient, and sustainable operational environment. progress—thereby demonstrating both their exceptional professional expertise and the power of collaborative teamwork.

This project comprises a highly specialized department and laboratory complex dedicated to integrated medical research and clinical services. By leveraging cutting-edge medical technologies and rigorous scientific inquiry, it aims to provide patients with comprehensive and precise medical care while simultaneously driving advancements in medical science. Far more than merely a venue for treating diseases, this complex serves as a frontier for the exploration and innovation of medical knowledge; it harnesses the collective wisdom and strength of interdisciplinary integration, striving to establish a highly efficient medical ecosystem characterized by a seamless transition from fundamental research to clinical application.

The Department of Pathology has been constructed in strict compliance with national and local regulations, placing a strong emphasis on processing specimens within an environment designed to prevent cross-contamination. It incorporates negative-pressure isolation and cleanroom technologies to uphold the highest standards of air quality and hygiene. The laboratory layout is meticulously planned based on the specific characteristics of the experiments conducted, delineating distinct functional zones to ensure that environmental parameters—including air quality, temperature, humidity, and cleanliness—are precisely controlled. Appropriate air conditioning, ventilation, filtration, and disinfection systems have been selected to align with the laboratory's classification requirements, with the aim of creating a work environment that is both safe and highly efficient. The lighting design integrates principles of safety, comfort, and efficiency, combining ample natural light with adjustable artificial light sources to meet varying requirements for brightness and color temperature. Furthermore, significant attention is devoted to noise management; soundproofing and sound-absorbing materials, along with specialized acoustic facilities, are utilized to mitigate operational noise from equipment, thereby fostering an atmosphere conducive to focused scientific research. This approach reflects a comprehensive consideration of environmental quality and a commitment to optimized design within the laboratory setting.

Material selection for the laboratory's interior fit-out prioritizes both practicality and safety. Preference is given to double-sided sandwich color steel panels—chosen for their ease of cleaning and disinfection, resistance to abrasion and wear, dust-free and crack-resistant properties, as well as their smooth, waterproof finish—for use as wall and ceiling panels. This ensures that fire safety standards meet, at a minimum, the B1 "flame-retardant" classification. The flooring consists of seamless, non-slip, and corrosion-resistant PVC or rubber materials; joints are precision-welded and finished flush, utilizing color-matched welding rods to maintain aesthetic consistency. The design deliberately avoids the inclusion of operable exterior windows, opting instead for sealed observation windows to enhance security and access control. Structurally, all junction points—including wall-to-wall, wall-to-floor, and wall-to-ceiling interfaces—feature curved transitional treatments, while the seams of the color steel panels are sealed using specialized sealant techniques to guarantee the strict airtightness of the laboratory environment.

The spatial design of the Department of Transfusion Medicine must carefully balance considerations regarding floor area, ceiling height, and optimal natural lighting and ventilation. It mandates the provision of independent access points and dedicated air conditioning systems to ensure environmental purity and effectively mitigate the risk of cross-infection. Interior finishes and materials are selected for their ease of cleaning, dust-resistant, antimicrobial, and anti-static properties; these standards are applied to all surfaces—including floors, walls, and ceilings—as well as every structural detail, with the aim of establishing a highly hygienic and safe working environment.
The configuration of laboratory benches and cabinetry has been meticulously planned. Based on functional requirements, storage capacity needs, and structural design specifications, the layout is optimized to enhance operational efficiency. By comprehensively integrating operational workflows, equipment characteristics, and spatial utilization strategies, the design ensures the high-performance operation and rigorous environmental control essential to the Department of Transfusion Medicine.

Strategically located within the inpatient department, the ward occupies a secluded and quiet zone situated in close proximity to the Internal Medicine and Auxiliary Diagnostic departments. It features a dedicated soiled utility area and an added access route to a dedicated soiled-waste elevator, thereby optimizing hygiene management. Each dialysis unit—comprising a machine and a patient bed—occupies a minimum floor area of ​​3.2 square meters; furthermore, spacing between beds and aisle widths are maintained at 1.2 meters and 1.3 meters, respectively, to safeguard patient privacy and facilitate operational efficiency. The dialysis room is equipped with air disinfection and air conditioning systems to ensure a fresh environment, supplemented by timely ventilation. The flooring is constructed from acid-resistant materials and incorporates floor drains; additionally, the facility is outfitted with oxygen supply and negative-pressure suction systems (either centralized or mobile units), ensuring comprehensive protection of both medical safety and environmental hygiene.

The facility utilizes high-standard construction materials and techniques to ensure an environment that is dust-free, safe, and durable. Both the ceilings and walls are constructed from dust-proof, smooth, and fire-resistant sandwich panels featuring a double-sided colored steel skin with a magnesium-oxide rock wool core. The edges are finished with channel-shaped aluminum trim, and all seams are sealed using neutral, ceramic-white silicone sealant; this effectively inhibits bacterial growth while ensuring the overall structural integrity and cleanliness of the space. The wall mounting system relies on adjustable floor tracks (50x100 mm specifications), securely anchored via expansion bolts to ensure enhanced structural stability. The flooring consists of Class B1 fire-retardant PVC sheeting—compliant with national laboratory standards—which offers excellent resistance to acids, alkalis, and corrosion, as well as high abrasion resistance, thereby meeting the rigorous material requirements of a laboratory setting.
Regarding attention to detail, all seams between the colored steel panels are sealed with neutral silicone sealant. Furthermore, at the junctions of different surfaces—such as where the floor meets the walls, where walls meet one another, and where walls meet the ceiling—a clever transition is created using R50mm-radius aluminum alloy curved profiles. This design is not only aesthetically pleasing but also facilitates easy cleaning, effectively eliminating hard-to-reach "dead zones" where dirt and contaminants might accumulate. Additionally, specific aluminum alloy curved treatments have been designed for columns and corners: convex corners feature external curved profiles, while concave corners feature internal curved inserts. Three-way intersection points are fitted with spherical caps, ensuring that every minute detail reflects a rigorous scientific approach combined with thoughtful, human-centric design considerations.

The laboratory design focuses on creating a fresh and bright environment, utilizing a color palette of white and blue combined with a minimalist scheme to minimize visual strain. The selection of laboratory bench materials prioritizes corrosion resistance and ease of cleaning; the benches feature multi-functional countertops and a tiered design to optimize equipment storage. The ventilation system operates with high efficiency—integrating fume hoods, exhaust fans, and air conditioning—to ensure a constant supply of fresh air and minimize the accumulation of contaminants. The lighting system balances natural light with artificial sources to eliminate shadows and glare, ensuring uniform and sufficient illumination across all work surfaces.

Regarding safety, the laboratory strictly adheres to fire safety codes, utilizing flame-retardant materials and providing clearly marked emergency exits and fire suppression equipment to ensure rapid evacuation. Air and water purification systems—incorporating filtration and UV sterilization technologies—maintain high environmental quality standards in full compliance with medical requirements. Particular attention is paid to ensuring that floors and walls are non-slip and easy to clean, and that the piping system is designed to be free of dead zones; all components are constructed from corrosion-resistant and pressure-tolerant materials, subject to regular maintenance.
Disinfection protocols are rigorous, employing ozone or UV sterilization technologies with continuous monitoring to verify their efficacy. Waste management adheres to medical waste classification principles, implementing procedures for safe, non-hazardous disposal and waste volume reduction. Furthermore, noise and vibration interference are controlled through the use of low-noise equipment and vibration-damping measures, thereby ensuring the precision and accuracy of experimental procedures. The electrical power supply is stable and reliable, supplemented by a backup power system to mitigate the risk of outages, thereby providing comprehensive assurance for the efficient and safe operation of the laboratory.

In summary, this health center construction project not only embodies the latest trends in modern medical facility development in terms of scale and design, but also demonstrates a high degree of professionalism and innovation in its construction management and technical implementation. It will undoubtedly serve as a new benchmark for elevating regional healthcare service standards and advancing the development of the healthcare sector.