webster hydraulic pump specs made in china

SUPER HIGH-QUALITY ENGINEERED WEBSTER DESIGN HYDRAULIC PUMP. THESE ARE BUILT AND TESTED IN THE USA TO ORIGINAL OEM SPECS IN OUR ISO-9001 COMPLIANT FACILITY.

WITH OVER 30 YEARS’ EXPERIENCE DESIGNING AND PRODUCING HYDRAULIC GEAR PUMPS YOU WILL FIND US HELPFUL AND PROFESSIONAL. SUPPORTING YOU TO GET YOUR EQUIPMENT BACK IN OPERATION QUICKLY!

Identify your hydraulic pump? Sounds easy enough, but you might be surprised. These hydraulic pumps can look very similar, but even the slightest difference could mean the difference of thousands of dollars worth of downtime. I feel like a broken record on this one, don’t get me wrong its important to know what you’re working with and having accurate information is key to being able to make an informed decision. We have put together a quick guide to help you determine what type of hydraulic pump you have so be sure to check it out below!

It is important to identify hydraulic pumps as a lot of them looks similar. It can be hard enough to know what the product is without actually knowing what it does and the specifications that are needed. To avoid any future problems with any systems, it is best to take this chance now and find out what you need. This article gives you a step by step process on how you can identify different type of hydraulic pumps so use it as reference.

There are many types of hydraulic pumps. They can be divided into two groups, positive displacement and centrifugal. Positive displacement pumps use a mechanism to create an increase in pressure or flow by reducing the volume of the pumped liquid, for example by changing its area or speed of movement. Centrifugal pumps do not generally change the volume of the liquid but rather accelerate it to increase the pressure at the outlet and therefore the discharge velocity.

Rotary screw pumps are used for high-pressure applications and can deliver high volume with very low pressure loss. They feature a rotating helical screw that forces the liquid into the pump chamber, where it expands and pushes against the walls of the chamber. The expanding liquid then turns another helical screw that forces more liquid into the chamber, creating a positive displacement effect that increases in efficiency as more turns of the screws occur per revolution of the shaft. This type of pump has no valves or seals to wear out and requires little maintenance.

Piston pumps use pistons to compress and expand liquids at high pressures and volumes; these pumps are typically used for low-pressure applications and lower flow rates than rotary screw pumps. Piston pumps have moving parts that wear out over time but are inexpensive compared to other types of hydraulic pumps because they only require low amounts of power from an electric motor or engine to operate efficiently at high pressures.

Cavitation is a phenomenon where a liquid loses its pressure faster than it can be replenished, resulting in bubbles forming at the surface of the liquid. When these bubbles collapse, they create shock waves that damage the pump’s impeller. These shock waves can also cause wear on other parts of the pump, such as bearings and seals.

Properly sized pumps will avoid cavitations and improve efficiency. The most common way to determine if your pump is properly sized is to check its horsepower rating compared with the horsepower required to run your equipment. If the horsepower rating of your pump is less than what’s required by your equipment, you need to replace it with a larger one.

Pumps are essential parts in the industry of energy, so they must be more safe and reliable. If a pump is not well identified, the problems may increase. Therefore, it is necessary that we can identify the different types of pumps quickly and accurately. This paper will firstly introduce several common hydraulic pumps and then give you some specific tips how to identify them.

Check for a serial number on one side or another of the main body of your hydraulic pump. It may be hard to find, but it should be there somewhere. The serial number is a great way to ensure that you have received an authentic replacement part. If no such information is available on your pump, then you should consider purchasing another unit from our website or another supplier.

The first letter represents the manufacturer. The second letter is usually a number that indicates the year of manufacture. The third letter may be a number, but it will never be more than four digits long. The fourth and fifth digits are used to identify each pump within the series.

We use an industry standard 2-digit code system to identify hydraulic pumps. This code will be stamped on the side of the pump or on its plate (see image below). If this code is missing from your pump then you can easily find it in our online database:

Kawasaki hydraulic pumps are used on a variety of machines. There are many different models with different part numbers and configurations. The following information is provided to help you identify your particular Kawasaki pump.

All Kawasaki hydraulic pumps have a part number that starts with the letter “H”. This letter is followed by some numbers and letters which indicate the model number for your machine. For example, if your machine has a serial number starting with “16”, then it will have an H16 pump. If your machine has a serial number starting with “17”, then it will have an H17 pump.

Kawasaki has several different parts numbers for each model number depending on the configuration of the pump and whether or not it comes with accessories such as mounting brackets or wiring harnesses. You can tell what configuration your pump has by looking at its pictures below.

The part number and serial number are printed on a sticker affixed to the pump. This is the easiest method of identifying your Eaton hydraulic pump, but it may not be available if you need to replace your Eaton hydraulic pump immediately.

The part number and serial number are stamped into the side of the pump casing, making them visible with some effort but requiring disassembly in order to read them. This can be done in-house without sending your hydraulic pump back to us for service or replacement.

Series 800 — These are industrial duty pumps with capacities ranging from 10 to 2,500 gallons per minute (gpm) at pressures up to 3,000 psi and flow rates up to 20 gpm at 4,000 psi.

Series 700 — These pumps are designed for high pressure applications requiring high volumes of oil and water at pressures up to 3,000 psi. The pumps have capacities ranging from 5 to 1,200 gpm at pressures up to 3,000 psi and flow rates up to 25 gpm at 4,000 psi.

Series 600 — These pumps are designed for high volume applications requiring high pressure capability at low speeds. They are available with capacities ranging from 5 to 1,200 gpm at pressures up to 3,000 psi and flow rates up to 25 gpm at 4,000 psi.

Parker is a brand of hydraulic pump that offers a full line of pumps for industrial and commercial applications. They are designed for use in high-pressure, high-temperature and low-volume applications. Parker Hydraulic Pumps are ideal for use in construction, mining, agriculture and other industries where high pressure is needed.

Parker Hydraulic Pumps come in a variety of styles and sizes with different features to suit your needs. When you need one of these pumps installed on your equipment, it is important to know what type you have so we can find the correct replacement parts for it when needed. The following information may help you identify your hydraulic pump:

Vickers is one of the world’s largest manufacturers of hydraulic pumps. The company has been producing pumps since 1825 and continues to innovate new products today.

Vickers pumps are identified by their model numbers, which provide information about the pump’s specifications. The first two digits of a Vickers pump number indicate the size of the cylinder; the third digit indicates the type of drive system (if any); and the fourth digit indicates whether the pump is for high or low pressure operation.

For example: A V-PVC-A-7 pump has a 2-inch diameter cylinder, no gearbox, operates at high pressure and is designed for use with air or oil as its working fluid.

Webster hydraulic pumps are used in many industries and applications, including agriculture, construction, mining, and marine. They are also used in the automotive industry and other areas where high pressure is required. In order to use a Webster pump properly and safely, it is important for you to be able to identify what type of pump you have. You can determine this by looking at the label on the side of your pump or by checking with a local supplier. If you cannot find this information, there are some basic differences between the different types of pumps that will help you determine what kind of Webster pump you have.

There are four basic types of Webster hydraulic pumps: diaphragm pumps, piston pumps, rotary lobe pumps and gear pumps. Each type has its own unique features that make it stand out from the others.

Rexroth is a German company specialized in manufacturing of hydraulic components. The company also makes pumps, motors and valves among other things. Rexroth has been in business since 1924 and has over 100 years of experience in the field of hydraulics.

There are many different types of Rexroth pumps, but they all have one thing in common: they are all made according to ISO standards. These standards ensure that all pumps are made with the same quality, which means that you can expect them to last for a long time.

Rexroth hydraulic pump identification can be done by looking at the model number printed on the side of your pump’s casing. There is no need to worry about getting this wrong though because each model number follows a certain pattern so it will be easy for you to identify your particular model no matter how many digits it has or whether or not it starts with an “R”.

The diagram below shows the basic parts of a Barnes hydraulic pump. The arrows indicate the flow of oil and the dotted lines represent the flow of air.

The diagram below shows the basic parts of a Barnes hydraulic pump. The arrows indicate the flow of oil and the dotted lines represent the flow of air.

3) – A check valve that prevents reverse flow through the pump when there is pressure on both sides of it (such as when powering a hydraulic cylinder).

4) – A check valve that prevents reverse flow through the pump when there is pressure on both sides of it (such as when powering a hydraulic cylinder).

Borg-Warner hydraulic pumps are a series of inline hydraulic pump designs, which have been used for many years. They can be identified by their “BW” logo on the face of the pump.

The most common Borg-Warner Pump is the BW35-Series Series Hydraulic Pump. This pump was used on most GM vehicles from the early 70’s through the early 90’s and can be identified by its black base color and white lettering on its face plate.

These pumps were very reliable until they started to wear out around 100k miles or so due to internal wear over time. If you have a later model vehicle with this type of pump then you may want to consider replacing it with a new one before it fails completely, as these pumps are hard to find and expensive if you do find them.

The cross hydraulic pump is a type of centrifugal pump used in the oil and gas industry to extract oil from an underground reservoir. The cross hydraulic pump is often used in tandem with other pumps, which are placed in sequence and act as a closed system. The closed system ensures that each pump provides the same amount of pressure and flow.

The cross hydraulic pump can be identified by its distinctive shape and size, as well as its operational characteristics. A cross hydraulic pump has two impellers at right angles to one another, allowing for a higher flow rate than other types of centrifugal pumps. It also uses an axial impeller design, which is unique from other types of centrifugal pumps.

The Danfoss Hydraulic Pumps are used in many industries and they are very important products in this world. The main purpose of these pumps is to move fluids such as oil or water. If you want to know how to identify the model number of Danfoss hydraulic pump, then you can read our article below and find out how to do it.

The first step is to find out if your model number is written on a sticker or etched into the side of your pump. The sticker will tell you what type of pump you have and where it was manufactured. The etched information will tell you more about the specifics of your product, such as its size, horsepower rating and more!

If you cannot find your model number on either sticker or etched info, then there could be no way for you to tell which model it is without contacting Danfoss directly for help. They have many different types of pumps that they manufacture and each one has a different set of numbers associated with them so they can easily identify what kind of product it is that they need to send out to someone who needs their help!

The Haldex BH series of hydraulic pumps are used in the majority of vehicles that use Haldex. They come in different models depending on the application and are rated from 1.0 to 3.0 bar (15 PSI) pressure output. The model is normally printed on a sticker on the top of the pump, but if this has been lost or damaged you can still work out which one you have by looking at the following chart:

Muncie’s hydraulic pump identification system was started in 1986 when they introduced the “S” series rear ends. The “S” stands for “Superior”. The numbers are as follows:

The Permco brand is a familiar name in the high-end hydraulic pump market. They are known for their commitment to quality and reliability. Their pumps are covered by a lifetime warranty, so you can buy with confidence.

Permco makes both air-cooled and water-cooled hydraulic pumps in various sizes and configurations. Their pumps are commonly used in applications such as mining equipment and construction equipment.

The first step in determining a hydraulic pump is to determine the flow rate of the system that you are servicing. This information can be found in the specifications of the system. It will be expressed in gallons per minute (gpm) or liters per minute (lpm).

The next step is to calculate the pressure required to lift, push or pull whatever it is that you need to do with your hydraulic system. This can be done by using the following formula:

Once you have determined this value, it is time to choose a pump that will provide sufficient flow at this pressure level. This can sometimes be done by examining catalogs and selecting a pump that has similar characteristics as your existing pump. If this does not work, contact us and we will be happy to recommend an appropriate replacement component for your application.

The type of loads you need to move. If you are using a hydraulic pump for load handling, then you need a high-pressure unit that can handle high pressure and flow rate.

If you want to use your pump for other purposes like providing power for machines, then you should consider choosing a lower-pressure unit with a lower flow rate.

The size and weight of the load you need to move. The size of your load will determine the kind of pump you should use. If your load is small, then it will require less power than a larger load that is heavier in weight and size.

The environment where your equipment will be used. You might need an oil-lubricated or wet-type hydraulic pump if your equipment will be used in an environment where there is water or moisture present such as construction sites or mining operations where there is water involved in the process.

I have a tandem pump setup on my front loader. The pump is an older model with no markings or serial number. I need to know the exact make and model so I can order parts for it.

My question is, does anyone know where I can find some kind of identification for this type of pump? It looks like it has two cylinders mounted back to back and the pistons are connected together by a rod. It also has two pumps mounted to the same base plate, but they are not connected together in any way.

A gear pump is a device that uses the principle of hydrodynamic lubrication in order to transport fluids. It works by placing a gear-like set of blades in a container filled with fluid and rotating the blades at a high speed. As the blades move through the fluid, they create low pressure areas on either side of each blade relative to the surrounding fluid. This difference in pressure causes a net flow of fluid into the low pressure area created by each blade. The net flow of fluid through each opening creates a positive displacement pump capable of generating high discharge pressures when driven at high speeds.

Gear pumps are widely used as industrial pumps for liquids where high discharge pressures are required and where contamination prevention is important (such as in pharmaceutical applications). There are many different types of gear pumps, with variations in design and construction depending on application requirements.

QCC took over the manufacture of the Webster & CP pumps and motors product families using the original tooling, assembly and test procedures transferred to us from Danfoss the Original Equipment Manufacturer (OEM). These products are exact matches to the original equipment part numbers and have been in production for many years with QCC.

For more than 60 years, Webster has been synonymous with superior quality, high performance gear pumps and motors. QCC has been manufacturing the Webster B, YB and YC product lines since 2004. In 2010, QCC extended its gear pump and motor offering with the transfer of the CP product line from Danfoss to QCC. The Webster/QCC line of gear products ranges from 0.06 cubic inches per revolution to 9.89 cubic inches per revolution (1.80 to 162 cubic centimeters) with mounting flanges 4F17, SAE A, SAE B and SAE C mounts. Options include flow divider models and multi-section pumps. K Series hydraulic pumps and motors provide the ultimate in flexibility, with numerous displacements, features, and shaft/port options.

QCC now manufactures K Series (formerly Danfoss) Pumps and Motors which have an excellent reputation for rugged, dependable performance at continuous pressures to 3000 psi (207 bar) and speeds to 3000 rpm. Applications include in construction, agriculture, lawn/turf care, cement mixers, fan drives, power steering and more. We also have also resurrected many of the formerly “obsolete” models to support our customers’ needs including PTO hydraulic power supply systems for agricultural applications.

Webster PTO (Power Take-Off) units are tractor-driven, completely self contained hydraulic power supply systems for agricultural applications. They mount on a tractor PTO shaft to provide hydraulic power for front end loaders, snow plows, mowers, spreaders, log splitters, post hole augers, and other hydraulic tools.

Available in 540 and 1000 rpm models, Webster PTO units feature lightweight high strength aluminum alloy housings, and hardened steel shafts & gears. At the heart of the PTO is a proven Webster YC Series pressure balanced hydraulic pump with a built-in relief valve, set at 2250 psi (155bar). Other standard features include reservoir, filler/breather and sight glass to insure proper fluid level.

The historical region now known as China experienced a history involving mechanics, hydraulics and mathematics applied to horology, metallurgy, astronomy, agriculture, engineering, music theory, craftsmanship, naval architecture and warfare. Use of the plow during the Neolithic period Longshan culture (c. 3000–c. 2000 BC) allowed for high agricultural production yields and rise of Chinese civilization during the Shang Dynasty (c. 1600–c. 1050 BC).multiple-tube seed drill and the heavy moldboard iron plow enabled China to sustain a much larger population through improvements in agricultural output.

For the purposes of this list, inventions are regarded as technological firsts developed in China, and as such does not include foreign technologies which the Chinese acquired through contact, such as the windmill from the Middle East or the telescope from early modern Europe. It also does not include technologies developed elsewhere and later invented separately by the Chinese, such as the odometer, water wheel, and chain pump. Scientific, mathematical or natural discoveries made by the Chinese, changes in minor concepts of design or style and artistic innovations do not appear on the list.

Philon of Byzantium (3rd or 2nd century BC)chain drive and windlass used in the operation of a polybolos (a repeating ballista),chain pumps which had been known in China since at least the Han Dynasty (202 BC – 220 AD) when they were mentioned by the Han dynasty philosopher Wang Chong (27 – c. 100 AD),clock tower built at Kaifeng in 1090 by the Song Chinese politician, mathematician and astronomer Su Song (1020–1101).

Escapement, hydraulic-powered (use in clock tower): The escapement mechanism was first described for a mechanical washstand by the Greek Philon of Byzantium who also indicated that it was already used for clocks.Yi Xing (683–727) of the Tang Dynasty (618–907) for his water-powered celestial globe in the tradition of the Han dynasty polymath and inventor Zhang Heng (78–139), and could be found in later Chinese clockworks such as the clock towers developed by the military engineer Zhang Sixun (fl. late 10th century) and polymath inventor Su Song (1020–1101).striking clock.pendulum resting and releasing its hooks on a small rotating gear wheel, the early Chinese escapement employed the use of gravity and hydraulics.waterwheel (which acted like a gear wheel) would be filled one by one with siphoned water from a clepsydra tank.

air conditioning, the Han Dynasty craftsman and mechanical engineer Ding Huan (fl. 180 AD) invented a manually operated rotary fan with seven wheels that measured 3 m (10 ft) in diameter; in the 8th century, during the Tang Dynasty (618–907), the Chinese applied hydraulic power to rotate the fan wheels for air conditioning, while the rotary fan became even more common during the Song Dynasty (960–1279).Georg Agricola (1494–1555).

archaeological site in Anatolia (Kaman-Kalehoyuk) and is about 4,000 years old.East Africa, dating back to 1400 BC.Falcata were produced in the Iberian Peninsula, while Noric steel was used by the Roman military.cast iron from the late Spring and Autumn period (722–481 BC), produced steel by the 2nd century BC through a process of decarburization, i.e. using bellows to pump large amounts of oxygen on to molten cast iron.Liu An (179–122 BC). For steel, they used both quenching (i.e. rapid cooling) and tempering (i.e. slow cooling) methods of heat treatment. Much later, the American inventor William Kelly (1811–1888) brought four Chinese metallurgists to Eddyville, Kentucky in 1845, whose expertise in steelmaking influenced his ideas about air injection to reduce carbon content of iron; his invention anticipated the Bessemer process of English inventor Henry Bessemer (1813–1898).

pestle and mortar to pound and decorticate grain, which was superseded by the treadle-operated tilt hammer (employing a simple lever and fulcrum) perhaps during the Zhou Dynasty (1122–256 BC) but first described in a Han Dynasty (202 BC – 220 AD) dictionary of 40 BC and soon after by the Han dynasty philosopher and writer Yang Xiong (53 BC – 18 AD) in his hydraulic power, which the Han dynasty philosopher and writer Huan Tan (43 BC – 28 AD) mentioned in his Xinlun of 20 AD, although he also described trip hammers powered by the labor of horses, oxen, donkeys, and mules.waterwheels were made in subsequent Chinese dynasties and in Medieval Europe by the 12th century.Pliny, Roman Empire by the 1st century AD.

Lewis, Michael (2000b), "Theoretical Hydraulics, Automata, and Water Clocks", in Wikander, Örjan,Handbook of Ancient Water Technology, Technology and Change in History, 2, Leiden, pp. 343–369 (356f.), ISBN 90-04-11123-9.

Kawasaki Precision Machinery (Suzhou) Ltd. was founded in Suzhou, Jiangsu, China in 2005 to manufacture and supply Kawasaki hydraulic components such as hydraulic pumps and motors in China. In 2015, the company started producing robots in addition to hydraulic products. This is Kawasaki’s second manufacturing facility for industrial robots after the first in Akashi, Japan.