1. د پامپ هیدرولیکي په اړه
د هیدرولیک سیستم معمولاً لاندې شامل دي: د هیدرولیکی توان منبع (پامپ)، د عملونو اجزا (هیدرولیکي سلندر یا موتور)، کنټرول اجزا، او همراه اجزا. دا یوه مهمه جز نیول شوی دی - د هیدرولیکي ترانسفورمر. د هیدرولیکي ترسیم او د الکترونیکي ترسیم ترمنځ ختیځ سره مشابهت لري، او د هیدرولیکي کنټرول سیستمونه او د الکترونیکي کنټرول سیستمونه د وړاندې کارکوونکو او پارامتراتو له لارې د مشابهت په توګه مقایسه کیږي. که څه به د یو الکترونیکي سیستم ته د ترانسفورمر نه وي؟ د هیدرولیکي ترانسفورمر د هیدرولیکي ترسیم او کنټرول سیستمونو لپاره یو ضروري او غیر قابل تعویض جز دی.
د مستقیم فشار هیدرولیکي شبکې جوړول، لوی هیدرولیکي سیستمونه او زیرسیستمونه جوړول، ډیری بارونو د مستقل کنټرول کول، او د ماشینی-هیدرولیکي ترکیب کول د معاصر هیدرولیکي تکنالوژۍ د اجباري روندونه دي. د هیدرولیکي ترانسفورمر په ډیری هیدرولیکي سیستمونو کې پراخ کارول شي او یو کلیدي هیدرولیکي جز وي.
اوس د "معمول" او "نوی" نوعونه د هیدرولیکي ترانسفورمر په تحقیق کې وجود لري، که دا داخلی او بین المللي توګه د آزمایشاتو مرحله کې دی او هیڅ یو پخته، صنعتي سطح د مارکیټ پرتله کولو لپاره نه دی. دا د فشار تنظیم کولو لپاره طراحی شوي دي او د تنظیم کولو د محدوده محدوده دی، د "فشار تنظیم کونکی" د "هیدرولیکي ترانسفورمر" څخه وړاندې دقیق نوم دی.
یو پیټنت تکنالوژۍ یو نوی نوع د هیدرولیکي ترانسفورمر معرفی کوي چې موجوده طرحونه په برخه کې پریښودل کوي. د لوی سرعت سره چرخولو د روټر کارولو په واسطه، دا د مستمر او پایدار فشار زيادول او کم کولو راولي کوي، او د یو واقعي "ترانسفورمر" د مفهومي تعریف، کارکوونکي مطالبو او عملی کارونو په توګه پرمختګ کوي. د دې نوی هیدرولیکي ترانسفورمر کارولو له لارې د هیدرولیکي سیستمونو کې د عالي کیفیت، مختلف فشار د مستقیم فشار مسیرونو جوړولو امکان پيدا کیږي. د هیدرولیکي اجزاو د "معیاري فشار"، "معیاري توان"، "معیاري حجم"، او "معیاري دوران" پارامتراتو د وړاندې عملي معنی پیدا کیږي. دا د اجزاو انتخاب، سیستم طراحی، کارکوونکي مطابقت، کارکوونکي افزایش، او تجهیزات د کنټرول او تشخیص لپاره پیښه او راحتي اوزار پراخوي.
总而言之,这项专利的“液压变压器”填补了液压技术和组件市场的一个关键空白,并有望推动液压领域的技术变革。
The Patent: "A Hydraulic Transformer"
Technical Advantages of the Hydraulic Transformer:
Simple structure, compact size, lightweight
Low rotational inertia, fast response, high sensitivity
Large transformation ratio, stable and unaffected by system parameter fluctuations
Capable of both step-up and step-down pressure conversion, enabling pressure energy recovery
Secondary flow adjustable from 0 to maximum rated flow
Effective isolation between primary and secondary working media
Near-zero static loss, low dynamic power loss
Easy installation and maintenance-free operation
2. Application and Promotion of the Hydraulic Transformer
Conventional hydraulic systems are often load-sensing systems, which rely on numerous control valves, resulting in complex configurations and significant throttling losses. The pump and actuators are difficult to match optimally, and multiple actuators suffer from pressure coupling. Often, multiple pumps are required to supply different actuators. In contrast, a constant-pressure network offers high adaptability and efficiency. The hydraulic transformer is essential in such networks because it can:
Generate output pressure higher than the source pressure
Effectively decouple the load from the energy source, making load performance independent of source dynamics
Drive multiple loads at different pressure levels simultaneously
Enable independent control of multiple loads directly at the user end
Simplify system design, reduce manufacturing costs, and minimize throttling losses
The adoption of constant-pressure networks and modular design represents the inevitable direction of modern hydraulic technology, and the hydraulic transformer is the key enabler.
The hydraulic transformer not only transmits power but also transforms pressure and flow parameters, while providing isolation between primary and secondary media. As such, various liquid media—mineral oil, water, seawater, organic fluids, biofluids—can coexist in the same system while remaining isolated, enabling energy exchange. This makes the hydraulic transformer highly applicable in environmentally friendly, green, energy-saving, and pollution-control fields.
Moreover, the hydraulic transformer can recover energy from loads, especially those with potential energy (e.g., lifting mechanisms), making its energy-saving and environmental benefits undeniable. Upon closer examination of its structure and operational characteristics, it becomes evident that the hydraulic transformer can collect, concentrate, amplify, and transmit dispersed, weak, or disordered energy, transforming it into a usable and recoverable form.
It holds great potential in emerging green energy applications such as:
Recovery of residual energy from wastewater and exhaust gases
Utilization of low-head hydropower
Wind energy harvesting
More importantly, the hydraulic transformer enables the construction of a unified fluid power and control network that integrates liquid and gas phases with isolation and parameter conversion. Fluid power technology includes two branches: hydraulics (liquid) and pneumatics (gas), traditionally separated due to differences in medium and operating parameters. However, integrating them into a single network is now feasible.
By using the hydraulic transformer (which could later be renamed a "fluid pressure transformer") to isolate media and adjust parameter levels, hydraulics and pneumatics can be unified into a single fluid power network. This aligns with the evolving needs of modern manufacturing and market demands.
Existing technologies already demonstrate this potential:
Pneumatic-hydraulic intensifiers
Pneumatic-hydraulic valves
Hydraulic hammers
Though these are standalone applications, they highlight the complementary advantages of combining hydraulic and pneumatic technologies.
For example, in the rapidly advancing field of intelligent robotics, integrating hydraulic and pneumatic systems could dramatically improve robots’ ability to mimic human motion. When AlphaGo can elegantly play Go with physical hands, only then can it truly be called a "man vs. machine" showdown—not an exaggeration, but a reflection of market demand for technological advancement.
The emergence of the hydraulic transformer will drive the integration of pneumatic and hydraulic systems, enabling a new unified fluid power and control network. In this network:
Pneumatic components’ strengths—fast response, cushioning, elastic force retention—are combined with
Hydraulic components’ strengths—high power density, precision, fast transient response—
resulting in synergistic performance.
It is foreseeable that in the near future, a wide range of new components will emerge, forming integrated and modular units. Alongside the widespread adoption of the hydraulic transformer (or "fluid pressure transformer"), these systems will permeate various sectors of modern manufacturing.