Descrição do produto
Product Parameters
Technical Specifications of Syringe pump
| PARAMETER | SPECIFICATION |
| Applicable syringes | 5ml,10ml,20ml,30ml,50ml,60ml of any standard |
| Accuracy | +/- 2% with correct calibration |
| Rate mode | 50ml(60ml):0.1ml/h-2000.0ml/h (0.1ml/h or 1ml/h step) 30ml:0.1ml/h-1200.0ml/h (0.1ml/h or 1ml/h step) 20ml:0.1ml/h-800.0ml/h (0.1ml/h or 1ml/h step) 10ml:0.1ml/h-400.0ml/h (0.1ml/h or 1ml/h step) 5ml: 0.1~200ml/h (0.1ml/h or 1ml/h step) (Programmable 0.01ml/h~9999.9ml/h) |
| Time Mode | SOL. VOL:0.1-9999.9ml (0.1ml step) TIME:00:01-99:59min (1min step) |
| Dose Mode: | Volume:0.1-999.9ml(0.1ml step) DRUG MASS:0.1-999.9mg 0.1mg step) DOSE:0.001-9999ug/kg/min(0.001ug/kg/min step) WEIGHT:0.1-300kg(0.1kg the least step) |
| Total Volume Range | 0.1-999.9ml (0.1 ml step) |
| Drug library Mode | 10 categories of drugs, amounts to 2000 kinds of drug names, 17kinds of dose units, such as ug/kg/min, mg/kg/min,etc. Makes drug dispensing more convenient and safer. (Available for SP3 only) |
| Sequential mode | Available (Only for SP3) |
| KVO Rate | 0.1~5.0 ml/h, Programmable and adjustable |
| DPS dynamic pressure | 24 levels, 30kPa-160kPa (Programmable and adjustable) |
| Alarms | Syringe Holder Loose ,Syringe Plunger Disengagement, Syringe Flange Insertion Error ,Syringe Not Calibrated, Occlusion, Syringe Empty, Rate Abnormal, Battery Empty, No Battery, Infusion Complete, Syringe Near Empty, No Action, Battery Low. Three levels of alarm volume LOW, MEDIUM or HIGH |
| Bolus Volume | Range: 1.0~50.0ml, (0.1ml step) |
| Interface | RS-232 |
| Brightness | 1~10 levels can be selected |
Company Profile
———-PROFESSIONAL MANUFACTURER OF MEDICAL PUMPS———-
Our Advantages
1. High quality product. Our team has focused on R&D and production of infusion and syringe pumps for more than 15 years.The pumps are all passed CE certificate(TUV-SUD ) and ISO13485.
2. Professional service. Our team will recommend suitable products according to your requirement. Experienced engineers will provide free after-sales service and help you better use our pumps.
3. Quick response. Our sales will reply your inquires in detail within 24 hours.
4. Timely delivery. The strong supply capacity can guarantee it.
5. Three-years warranty for free.
6. OEM Accepted. Your logo can be printed on the products.
PERGUNTAS FREQUENTES
One-Stop Medical Equipment Supplier
1.What is your warranty for the products?
Two year for free.
2.What is your after-sales service?
We provide technical support through operating manual and video; Once you have questions, you can get our engineer’s prompt response by email, phone call, or training in factory. If it’s hardware problem, within the warrantyperiod, we will send you spare parts for free, or you send it back then we repair for you freely.
3.What is the delivery time?
We have shipping agent, we can deliver the products to you by express, air freight, sea. Below is some delivery time for your reference:Express:UPS,DHL,TNT,ect (door to door),7-10 days
Hand carry: Send to your hotel, your friends, your forwarder, your sea port or your warehouse in China. Air freigt(from airport to airport): 3-10 days
Sea(any sea port):Mombasa(30 days),Port Xihu (West Lake) Dis.g(12 days),Manila(10 days),Lagos (45 days), Guayaquil(45 days)
4.How to place the order? What is your lead time of the products?
40% of our products are in stock, 50% of the products need 3-10 days to produce, 10%of the products need 15-30 days to produce.
5.What is your payment term?
Our payment term is Telegraphic Transfer in advance, Western union, MoneyGram, Paypal, Trade Assurance, ect…
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| Classification: | Physiological Functions of Diagnosis and Monitoring Equipment |
|---|---|
| Type: | Syringe Pump |
| Certification: | CE, MSDS, ISO13485 |
| Group: | Patient |
| Drug Library: | up to 1030 Drugs Are Provided. |
| Certificate: | CE, ISO13485 |
| Samples: |
US$ 230/Piece
1 Piece(Min.Order) | |
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| Personalização: |
Disponível
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Qual é o impacto da altitude no desempenho da bomba de vácuo?
O desempenho das bombas de vácuo pode ser influenciado pela altitude em que elas são operadas. Aqui está uma explicação detalhada:
Altitude refere-se à elevação ou altura acima do nível do mar. À medida que a altitude aumenta, a pressão atmosférica diminui. Essa diminuição da pressão atmosférica pode ter vários efeitos sobre o desempenho das bombas de vácuo:
1. Redução da capacidade de sucção: As bombas de vácuo dependem do diferencial de pressão entre o lado da sucção e o lado da descarga para criar um vácuo. Em altitudes mais elevadas, onde a pressão atmosférica é menor, o diferencial de pressão disponível para a bomba trabalhar é reduzido. Isso pode resultar em uma diminuição da capacidade de sucção da bomba de vácuo, o que significa que ela pode não ser capaz de atingir o mesmo nível de vácuo que atingiria em altitudes mais baixas.
2. Nível de vácuo final mais baixo: O nível de vácuo máximo, que representa a pressão mais baixa que uma bomba de vácuo pode atingir, também é afetado pela altitude. Como a pressão atmosférica diminui com o aumento da altitude, o nível de vácuo máximo que pode ser atingido por uma bomba de vácuo é limitado. A bomba pode ter dificuldade para atingir o mesmo nível de vácuo que atingiria no nível do mar ou em altitudes mais baixas.
3. Velocidade de bombeamento: A velocidade de bombeamento é uma medida da rapidez com que uma bomba de vácuo pode remover gases de um sistema. Em altitudes mais elevadas, a pressão atmosférica reduzida pode levar a uma diminuição na velocidade de bombeamento. Isso significa que a bomba de vácuo pode levar mais tempo para evacuar uma câmara ou sistema até o nível de vácuo desejado.
4. Aumento do consumo de energia: Para compensar a diminuição do diferencial de pressão e atingir o nível de vácuo desejado, uma bomba de vácuo operando em altitudes mais elevadas pode exigir maior consumo de energia. A bomba precisa trabalhar mais para superar a pressão atmosférica mais baixa e manter a capacidade de sucção necessária. Esse aumento no consumo de energia pode afetar a eficiência energética e os custos operacionais.
5. Variações de eficiência e desempenho: Diferentes tipos de bombas de vácuo podem apresentar diferentes graus de sensibilidade à altitude. As bombas de palhetas rotativas vedadas a óleo, por exemplo, podem apresentar variações de desempenho mais significativas em comparação com as bombas secas ou outras tecnologias de bombas. O projeto e os princípios operacionais da bomba de vácuo podem influenciar sua capacidade de manter o desempenho em altitudes mais elevadas.
É importante observar que os fabricantes de bombas de vácuo normalmente fornecem especificações e curvas de desempenho para suas bombas com base em condições padronizadas, geralmente no nível do mar ou próximo a ele. Ao operar uma bomba de vácuo em altitudes mais elevadas, é aconselhável consultar as diretrizes do fabricante e considerar quaisquer limitações ou ajustes relacionados à altitude que possam ser necessários.
Em resumo, a altitude em que uma bomba de vácuo opera pode ter um impacto em seu desempenho. A pressão atmosférica reduzida em altitudes mais elevadas pode resultar na diminuição da capacidade de sucção, em níveis mais baixos de vácuo final, na redução da velocidade de bombeamento e no possível aumento do consumo de energia. Compreender esses efeitos é fundamental para selecionar e operar bombas de vácuo de forma eficaz em diferentes ambientes de altitude.
How Do Vacuum Pumps Contribute to Energy Savings?
Vacuum pumps play a significant role in energy savings in various industries and applications. Here’s a detailed explanation:
Vacuum pumps contribute to energy savings through several mechanisms and efficiencies. Some of the key ways in which vacuum pumps help conserve energy are:
1. Improved Process Efficiency: Vacuum pumps are often used to remove gases and create low-pressure or vacuum conditions in industrial processes. By reducing the pressure, vacuum pumps enable the removal of unwanted gases or vapors, improving the efficiency of the process. For example, in distillation or evaporation processes, vacuum pumps help lower the boiling points of liquids, allowing them to evaporate or distill at lower temperatures. This results in energy savings as less heat is required to achieve the desired separation or concentration.
2. Reduced Energy Consumption: Vacuum pumps are designed to operate efficiently and consume less energy compared to other types of equipment that perform similar functions. Modern vacuum pump designs incorporate advanced technologies, such as variable speed drives, energy-efficient motors, and optimized control systems. These features allow vacuum pumps to adjust their operation based on demand, reducing energy consumption during periods of lower process requirements. By consuming less energy, vacuum pumps contribute to overall energy savings in industrial operations.
3. Leak Detection and Reduction: Vacuum pumps are often used in leak detection processes to identify and locate leaks in systems or equipment. By creating a vacuum or low-pressure environment, vacuum pumps can assess the integrity of a system and identify any sources of leakage. Detecting and repairing leaks promptly helps prevent energy wastage associated with the loss of pressurized fluids or gases. By addressing leaks, vacuum pumps assist in reducing energy losses and improving the overall energy efficiency of the system.
4. Energy Recovery Systems: In some applications, vacuum pumps can be integrated into energy recovery systems. For instance, in certain manufacturing processes, the exhaust gases from vacuum pumps may contain heat or have the potential for energy recovery. By utilizing heat exchangers or other heat recovery systems, the thermal energy from the exhaust gases can be captured and reused to preheat incoming fluids or provide heat to other parts of the process. This energy recovery approach further enhances the overall energy efficiency by utilizing waste heat that would otherwise be lost.
5. System Optimization and Control: Vacuum pumps are often integrated into centralized vacuum systems that serve multiple processes or equipment. These systems allow for better control, monitoring, and optimization of the vacuum generation and distribution. By centralizing the vacuum production and employing intelligent control strategies, energy consumption can be optimized based on the specific process requirements. This ensures that vacuum pumps operate at the most efficient levels, resulting in energy savings.
6. Maintenance and Service: Proper maintenance and regular servicing of vacuum pumps are essential for their optimal performance and energy efficiency. Routine maintenance includes tasks such as cleaning, lubrication, and inspection of pump components. Well-maintained pumps operate more efficiently, reducing energy consumption. Additionally, prompt repair of any faulty parts or addressing performance issues helps maintain the pump’s efficiency and prevents energy waste.
In summary, vacuum pumps contribute to energy savings through improved process efficiency, reduced energy consumption, leak detection and reduction, integration with energy recovery systems, system optimization and control, as well as proper maintenance and service. By utilizing vacuum pumps efficiently and effectively, industries can minimize energy waste, optimize energy usage, and achieve significant energy savings in various applications and processes.
What Is the Purpose of a Vacuum Pump in an HVAC System?
In an HVAC (Heating, Ventilation, and Air Conditioning) system, a vacuum pump serves a crucial purpose. Here’s a detailed explanation:
The purpose of a vacuum pump in an HVAC system is to remove air and moisture from the refrigerant lines and the system itself. HVAC systems, particularly those that rely on refrigeration, operate under specific pressure and temperature conditions to facilitate the transfer of heat. To ensure optimal performance and efficiency, it is essential to evacuate any non-condensable gases, air, and moisture from the system.
Here are the key reasons why a vacuum pump is used in an HVAC system:
1. Removing Moisture: Moisture can be present within an HVAC system due to various factors, such as system installation, leaks, or improper maintenance. When moisture combines with the refrigerant, it can cause issues like ice formation, reduced system efficiency, and potential damage to system components. A vacuum pump helps remove moisture by creating a low-pressure environment, which causes the moisture to boil and turn into vapor, effectively evacuating it from the system.
2. Eliminating Air and Non-Condensable Gases: Air and non-condensable gases, such as nitrogen or oxygen, can enter an HVAC system during installation, repair, or through leaks. These gases can hinder the refrigeration process, affect heat transfer, and decrease system performance. By using a vacuum pump, technicians can evacuate the air and non-condensable gases, ensuring that the system operates with the designed refrigerant and pressure levels.
3. Preparing for Refrigerant Charging: Prior to charging the HVAC system with refrigerant, it is crucial to create a vacuum to remove any contaminants and ensure the system is clean and ready for optimal refrigerant circulation. By evacuating the system with a vacuum pump, technicians ensure that the refrigerant enters a clean and controlled environment, reducing the risk of system malfunctions and improving overall efficiency.
4. Leak Detection: Vacuum pumps are also used in HVAC systems for leak detection purposes. After evacuating the system, technicians can monitor the pressure to check if it holds steady. A significant drop in pressure indicates the presence of leaks, enabling technicians to identify and repair them before charging the system with refrigerant.
In summary, a vacuum pump plays a vital role in an HVAC system by removing moisture, eliminating air and non-condensable gases, preparing the system for refrigerant charging, and aiding in leak detection. These functions help ensure optimal system performance, energy efficiency, and longevity, while also reducing the risk of system malfunctions and damage.
editor by CX 2024-04-09
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