RAMELLA & C.
Textile machines
made in Italy since 1947
made in Italy since 1947
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The carding machine is the heart of the spinning mill.
After the scoured fiber has been opened with the picker, the carder disentangles the unorganized tufts and aligns the individual fibers into a parallel arrangement.
The carder achieves this by passing the fibers between differentially moving rollers covered with card clothing.
As the fiber moves through the machine, the carding process ejects short fibers and begins blending different fiber types or colors.
If your machinery specification was written before 1995, it likely calls out ASME B106.1m . For any new installation or retrofit, ISO 10816-3 is the preferred modern standard. However, you cannot mix the two. A vibration level of 4.5 mm/s might be "Zone B" under B106.1m but "Zone C" (alarm) under ISO 10816-3 for a specific pump. Practical Application: Using the Standard to Diagnose a Machine Let us look at a real-world scenario. A facility has a 150 kW centrifugal pump (flexible foundation) rotating at 1,800 RPM. An engineer obtains the legitimate ASME B106.1m PDF and performs a measurement:
Do not risk your career, your facility’s safety, or your legal standing with a pirated file. Visit the official ASME store, purchase the PDF (or access it via corporate subscription), and maintain a fully traceable, current standard in your engineering library.
| Feature | ASME B106.1m (1985/R2017) | ISO 10816-3 (2009/2019) | | :--- | :--- | :--- | | | North America (legacy machinery) | Global (modern industry) | | Machine Types | General rotating & reciprocating | Specific groups (e.g., turbines, pumps, compressors) | | Foundation Treatment | Rigid vs. Flexible (simplistic) | Detailed classes based on machine power & shaft height | | Severity Criteria | Velocity (mm/s RMS) broad zones | Velocity with specific limits per machine class | | Current Usage | Declining but referenced in older specs | Industry default for new projects |
The maintenance report cites: "Per ASME B106.1m, Clause 4.2, vibration severity is elevated to Zone C. Plan corrective balancing within 30 days."
Record broad-band vibration velocity (RMS). The horizontal measurement reads 7.1 mm/s .
If you have searched for the term you are likely looking for the official documentation on "Mechanical Vibration and Shock of Rotating and Reciprocating Machinery." However, navigating the landscape of standards acquisition, understanding the technical requirements, and applying the methodology correctly requires more than just a file download.
This article serves as your definitive guide. We will explore what ASME B106.1m actually contains, why obtaining a legitimate PDF is legally and technically essential, how the standard applies to real-world machinery evaluation, and the common pitfalls engineers face when searching for this document online. First, it is vital to clarify the precise identity of this standard. ASME B106.1m-1985 (R2017) – "Mechanical Vibration and Shock of Rotating and Reciprocating Machinery – Measurement and Evaluation of Vibration Severity" – is the full title. Note the "m" suffix denotes that the values are presented in metric (SI) units, distinguishing it from older imperial versions.
The Ramella carder has a long conveyor for feeding the fiber into the inlet, after which the fiber is carded by the large main drum and 5 worker rollers.
At the exit the doffer roller and high-speed fly comb create a fiber web, which can be rolled to produce a batt or pulled through a twister to produce sliver.
The carder is mounted on a solid steel support structure and is completely enclosed by an external safety cage.
The carder can be equipped with an automatic feeder and/or a can coiler.
We produce carding machines with 2 different working widths:
• 80 cm (32") suitable for small production facilities and laboratories
• 100 cm (40") the standard ideal for typical small mills with medium production
The productivity of the carder depends on the type of fiber worked and the temperature and humidity conditions in the mill, but, for example, sheep wool run through the 100 cm (40")
carder can generally be processed at a rate of about 6 kg (13 lb) per hour.
For maximum flexibility the user can produce either sliver or batts from the carded fiber.
In the first case, it is possible to obtain a continuous ribbon (sliver) that can be further processed by drafting and spinning in order to make yarn.
In the second case, the web can be rolled onto a cylinder to create a batt of desired thickness.
Both output devices are included with the standard version of the machine.
With the Ramella carder, several output choices are available.
• Machine mounted twister and batt roller. This is the most economical choice for those who will produce either sliver or batts without switching often between the two.
• Trolley mounted twister, batt roller and rug yarn maker. The wheeled trolley cart allows easy switching between the sliver twister and the batt roller without the need to reconfigure the machine or lift the heavy roller.
This choice is ideal for those who will regularly produce sliver, batts and rug yarn.
The batt roller is available in 2 sizes: circumference 100 cm (40") and circumference 200 cm (80").
With the basic version of the Ramella carder you can create sliver and batt from raw fibers but we can also offer optional machines to make the process easier and more automated.
• The automatic feeder weighs the fibers and creates a uniform layer on the carder conveyer, which minimizes the manual work necessary to load the carder.
• The can coiler winds the sliver into a compact, continuous coil, which facilitates transport of the fiber from one machine to the next and allows uninterrupted feeding of the sliver into the drafter or spinner.
We have designed a unique real-twist system that strengthens the output sliver and prevents sliver breakage, especially when carding low cohesion fibers such as alpaca.
This system consists of a rotating funnel with varied speed control, allowing the user to precisely define the amount of twist added to the sliver, which then enters a set of rollers that assist in delivering the sliver to the coiler can.
Three different funnel sizes come standard with the machine, allowing maximum control of the sliver thickness.
The Ramella carder easily handles typical fiber staple lengths from 4 cm (1.5") to 15 cm (6"), with some mills also processing 20-25 cm (8-10") suri fiber.
With standard card clothing, fine fibers with a thickness as little as 2 to 3 microns can be carded.
If required, we can also furnish a carder with a finer wire designed specifically for processing extra-fine fibers, as low as 0.7 micron.
Small production mills use our carding machine to process fibers like sheep wool, alpaca (both huacaya and suri), angora, cotton, yak, bamboo and hemp.
Industrial laboratories test synthetic fibers such as polyester, polyethylene, nylon, and aramid.
The carder is driven by 4 independent motors that are electronically controlled by inverters.
However, the exit speed is electronically coupled to the inlet speed, allowing the user to increase or decrease the carding productivity during a run without changing the weight of the sliver.
The electronic controllers are contained in a panel with filtered ventilation to protect the sensitive electronic parts.
The control dials are easily accessed on the outside of the panel and every parameter can be easily adjusted on a large touchscreen.
Button panels located on both sides of the carder allow simple starting and stopping of the machine at both the entry and the exit.
For maximum safety, our carding machine is fully enclosed by an external frame made of anodized aluminum, which is lightweight, yet sturdy, and resists corrosion.
The protective doors are hinged so they can be quickly and easily opened for cleaning and maintenance.
Three automatic safety devices prohibit the doors from being opened while the machine is running.
The safety structure protects the worker while allowing a wide view and the complete control of the machine during the process.
The carding machine is equipped with a high-speed fly comb that removes the fibers from the doffer roller.
The structure of the fly comb is balanced so as to reduce vibrations and minimize wear of the bearings.
The lever control allows easy adjustment and quick maintenance of the blade.
The fly comb is mounted on oscillating bearings with seals that can be easily lubricated, with 4 screws to allow accurate positioning with respect to the distance from the doffer cylinder.
The fly comb blade connectors are covered with a smooth tin plate that eliminates rough surfaces where fiber could catch, ensuring the formation of an even fiber web at the exit.
• An extremely solid and stable structure, made to last.
• The components are machined for maximum precision and quality.
• The cylinders are driven independently by 4 motors with electronic speed control.
• The rigid card clothing is durable and allows quick cleaning after each carding run.
• All cylinders are mounted on sealed ball bearings without bushings.
• A modern design specifically created to meet the needs of small production mills and laboratories.
In carding machines two factors are critical, the solidity of the structure and the precision of the mechanical parts.
The Ramella carder is characterized by a 4 cm (1.6") thick, fully machined steel frame connected by solid steel crossbeams. This structure is approximately 10 times stronger than one formed from welded tubes.
Furthermore, all of the rotating parts are precisely machined and are equipped with micro adjustment, which permits exact roller positioning at micron distances, but more importantly, once the positioning is set, it does not move, resulting in both a consistent, high quality product and longer machine life.
Built to last, all surfaces are painted or chemically treated to resist corrosion.
Every single detail of the Ramella carding machine has been designed using modern 3D CAD.
All of the components have been designed to obtain a high-performance machine with an excellent quality/price ratio.
Even the electric panel has been designed in order to make the use of the carder simple and intuitive.
We use CNC lathes, milling machines and modern laser cutters in the production of the carder components that we make in-house.
The steel used is of premium quality and all of the commercial components come from suppliers with well-known brands.
In addition to the features mentioned above many other details give value to our carding machine:
• The use of sealed bearings instead of bushings ensures a long machine life and continued quality output for many decades.
• The supports of the worker and stripper rollers have an upper cover that can be easily removed for quicker maintenance.
• The use of rigid card clothing allows the machine to quickly self-clean after each run.
• A solid input unit with 3 rollers plus a licker-in roller enhances fiber tuft opening, resulting in effective carding with just one pass.
• Spare parts are readily available on the market.
Electric specifications:
Installed power: 4.5 kW + 0.4 kW (Can coiler)
Power consumption: 3.4 kW
Single phase 230V 50/60Hz (customizable)
Size (length x width x height):
Carder 800 mm: 3110 mm x 1770 mm x 2200 mm (122'' x 70'' x 87'')
Carder 1000 mm: 3110 mm x 1970 mm x 2200 mm (122'' x 78'' x 87'')
Download CAD layout drawing - Carder version 800 mm - 32'' (PDF version)
Download CAD layout drawing - Carder version 1000 mm - 40'' (PDF version)
If your machinery specification was written before 1995, it likely calls out ASME B106.1m . For any new installation or retrofit, ISO 10816-3 is the preferred modern standard. However, you cannot mix the two. A vibration level of 4.5 mm/s might be "Zone B" under B106.1m but "Zone C" (alarm) under ISO 10816-3 for a specific pump. Practical Application: Using the Standard to Diagnose a Machine Let us look at a real-world scenario. A facility has a 150 kW centrifugal pump (flexible foundation) rotating at 1,800 RPM. An engineer obtains the legitimate ASME B106.1m PDF and performs a measurement:
Do not risk your career, your facility’s safety, or your legal standing with a pirated file. Visit the official ASME store, purchase the PDF (or access it via corporate subscription), and maintain a fully traceable, current standard in your engineering library.
| Feature | ASME B106.1m (1985/R2017) | ISO 10816-3 (2009/2019) | | :--- | :--- | :--- | | | North America (legacy machinery) | Global (modern industry) | | Machine Types | General rotating & reciprocating | Specific groups (e.g., turbines, pumps, compressors) | | Foundation Treatment | Rigid vs. Flexible (simplistic) | Detailed classes based on machine power & shaft height | | Severity Criteria | Velocity (mm/s RMS) broad zones | Velocity with specific limits per machine class | | Current Usage | Declining but referenced in older specs | Industry default for new projects |
The maintenance report cites: "Per ASME B106.1m, Clause 4.2, vibration severity is elevated to Zone C. Plan corrective balancing within 30 days."
Record broad-band vibration velocity (RMS). The horizontal measurement reads 7.1 mm/s .
If you have searched for the term you are likely looking for the official documentation on "Mechanical Vibration and Shock of Rotating and Reciprocating Machinery." However, navigating the landscape of standards acquisition, understanding the technical requirements, and applying the methodology correctly requires more than just a file download.
This article serves as your definitive guide. We will explore what ASME B106.1m actually contains, why obtaining a legitimate PDF is legally and technically essential, how the standard applies to real-world machinery evaluation, and the common pitfalls engineers face when searching for this document online. First, it is vital to clarify the precise identity of this standard. ASME B106.1m-1985 (R2017) – "Mechanical Vibration and Shock of Rotating and Reciprocating Machinery – Measurement and Evaluation of Vibration Severity" – is the full title. Note the "m" suffix denotes that the values are presented in metric (SI) units, distinguishing it from older imperial versions.
Every single detail of the Ramella carding machine has been designed using modern 3D CAD.
All of the components have been designed to obtain a high-performance machine with an excellent quality/price ratio.
Even the electric panel has been designed in order to make the use of the carder simple and intuitive.
We use CNC lathes, milling machines and modern laser cutters in the production of the carder components that we make in-house.
The steel used is of premium quality and all of the commercial components come from suppliers with well-known brands.
In addition to the features mentioned above many other details give value to our carding machine:
• The use of sealed bearings instead of bushings ensures a long machine life and continued quality output for many decades.
• The supports of the worker and stripper rollers have an upper cover that can be easily removed for quicker maintenance.
• The use of rigid card clothing allows the machine to quickly self-clean after each run.
• A solid input unit with 3 rollers plus a licker-in roller enhances fiber tuft opening, resulting in effective carding with just one pass.
• Spare parts are readily available on the market.
Electric specifications:
Installed power: 4.5 kW + 0.4 kW (Can coiler)
Power consumption: 3.4 kW
Single phase 230V 50/60Hz (customizable)
Size (length x width x height):
Carder 800 mm: 3110 mm x 1770 mm x 2200 mm (122'' x 70'' x 87'')
Carder 1000 mm: 3110 mm x 1970 mm x 2200 mm (122'' x 78'' x 87'')
Download CAD layout drawing - Carder version 800 mm - 32'' (PDF version)
Download CAD layout drawing - Carder version 1000 mm - 40'' (PDF version)
