How thick can a Powermax 85 cut?

The Powermax 85 can cut materials up to 3/4″ thick with a fine cut nozzle and up to 1-1/4” thick with a standard cut nozzle. It has a recommended cut capacity of 1/4” mild steel and is able to mark up to 5/8” mild steel.

The Powermax 85 also has a high-performance drag cutting kit which allows the machine to cut up to 1-1/2” mild steel and 3/4” stainless steel. When cutting thicker materials, it is wise to pre-cut an outline with a handheld torch or cutting tip.

This process will minimize distortion from the plasma arc and speed up cutting time by concentrating heat input to a smaller area.

How many amps does a Hypertherm 85 pull?

The Hypertherm 85 has an input current of 15 amps when powered at 230 volts and 23 amps when powered at 400 volts. It also features a current range of 10 to 34 amps and a frequency of 50/60 Hz, allowing users to adjust power accordingly and provide the optimal performance and quality.

Additionally, the Hypertherm 85 has a patented consumable life gauge which displays the remaining cut capacity of the consumables installed in the torch instead of needing a secondary monitor.

How thick will a hypertherm 1000 cut?

The Hypertherm 1000 is capable of cutting materials up to 3/4″ thick. This is based on using a CleanCut® plasma series torch and a 12. 5 amp power supply. Additionally, with automated plasma cutting systems, the Hypertherm 1000 can cut up to 1″ thick material.

The thickness of material that the Hypertherm 1000 is capable of cutting is based on the type of material and its physical properties. Different materials require additional amps to effectively cut them and the maximum amps the Hypertherm 1000 can provide is 20A.

Depending on the material and metal thickness, the speed and quality of the cut may also vary.

How thick can a 80 amp plasma cutter cut?

An 80 amp plasma cutter typically has a maximum severance cutting thickness of 1/2”. For example, the Hypertherm Powermax 45 can cut up to 1/2” steel, aluminum and stainless steel at full power. However, plasma cutters can successfully cut thicker material if they are operated at lower current settings.

Typically, the theoretical cutting limit of most 80 amp plasma cutters is 3/4” to 1”. But keep in mind, cutting thicker material will require more time because the cutter will have to make multiple passes to complete the cut.

Additionally, the thicker materials may be harder for the torch to penetrate and may require the cutting speed to be reduced in order to get acceptable cut quality.

Is a Hypertherm Powermax 85 single phase?

No, the Hypertherm Powermax 85 is not single phase. It is an 115–230 V, 50–60 Hz 3-phase input machine. It has 360 V 3 phase torch voltage and also has a kilowatt output of 85. It has processes such as, air plasma cutting, gouging and marking.

This machine is also ideal for mechanized cutting, as it has an array of custom-engineered components, allowing for multiple cutting and gouging solutions. The Powermax 85 is designed for tough industrial applications such as those found in shipbuilding and similar heavy industries.

It is also designed to deliver exceptionally high levels of reliability, serving you for many years to come.

What is the difference between hypertherm 45 and 45xp?

Hypertherm 45 and 45xp are both plasma cutter systems manufactured by Hypertherm, but there are some differences between them. The Hypertherm 45 is a manual, hand-held plasma cutting system, while the 45xp is a fully automated robot-arm assisted cutting system.

The Hypertherm 45 offers maximum cutting speeds of up to 14 inches per minute, whereas the 45xp has speeds of up to 33 inches per minute. The Hypertherm 45 has an output current of 40 amps, whereas the 45xp has up to 50 amps.

The Hypertherm 45 accepts a variety of different torch types, including drag, circle, and ring cutters, while the 45xp only takes a specific type of torch.

The Hypertherm 45 is best suited to cutting thick plate and greater workpiece dimensions, while the 45xp is ideal for cutting thin sheet materials and intricate shapes with superior speed and accuracy.

The Hypertherm 45 is much less expensive than the 45xp, and its warranty is also less extensive than that of the 45xp.

How long do Hypertherm consumables last?

The amount of time that Hypertherm consumables last will vary depending on the type of consumable being used and the working environment in which it is being used. Generally, Hypertherm consumables can last anywhere from several hours of continuous use to several years of intermittent use.

All Hypertherm systems come with a manufacturer’s warranty that covers consumables that are worn out within a certain amount of time.

For oxyfuel systems, consumables such as cutting tips and nozzles typically last for several hundred inches of cut before needing to be replaced. The rule of thumb is that on average a cutting tip should last for approximately 1/8” of cut (depending on the material being cut, the oxygen pressure, the cutting speed, and a few other factors).

For plasma systems, such as the Powermax, Hypertherm Extended life nozzles and electrodes can last for up to 10,000 cuts before needing to be replaced. Consumables such as shield caps, retaining caps, swirl rings, and other parts of the torch assembly will need to be changed more often, typically after around 500 to 1,000 cuts.

It is important to always refer to the operator’s manual in order to know what consumables need to be replaced and at what intervals.

What is pierce delay in plasma cutting?

Pierce delay is a setting in plasma cutting that refers to the amount of time the arc is allowed to remain on during the piercing process of a material before the torch begins to move. The exact time delay is determined by the thickness of the material being cut, the cut amperage, and the type of torch being used.

Generally, too little pierce delay can lead to an inadequate cut start, while too much pierce delay can cause an excessive amount of dross around the pierce point, or even nozzle cracking or warping.

The optimal pierce delay is usually between 0. 5 – 1. 5 seconds and can be adjusted based on the cutting conditions. Having an accurate and precise pierce delay setting is essential for getting the best results from a plasma cutting application.

How many amps does a plasma cutter draw?

The amount of amps a plasma cutter draws depends on the model or type of plasma cutter that you have. A general rule of thumb is to expect to draw between 8 to 30amps for most standard diameter plasma cutting applications.

However, different types of plasma cutters may have a higher or lower amp rating. For example, a lightweight plasma cutter may draw a lower amp rating than a full-sized plasma cutter. For very thick materials, a higher amp capacity plasma cutter is needed to properly cut the material.

Higher amp ratings also help reduce stress on the equipment by allowing it to cut the material faster and smoother. It’s important to refer to the manufacturer’s specs for the exact amperage draw of your particular model.

Additionally, you may have to adjust the amperage on your particular plasma cutter to adjust the speed and quality of the cut.

What amp breaker is needed for plasma cutter?

The amperage breaker required for a plasma cutter will vary depending on the type, size, and wattage of the plasma cutter. Generally, a minimum 30 amp breaker is recommended for machines with a rating of up to 35 amps.

However, a 50 amp breaker may be necessary if you are running a machine with a power rating of more than 35 amps. In addition, the thickness of the material being cut will also affect the required amperage since thicker materials require more power in order to cut through.

When calculating the required amperage, the plasma cutter’s rated amperage must be multiplied by 1. 25 to ensure the machine is not overloaded. It is important to accurately calculate the amperage for your plasma cutter in order to avoid any potential damage that may occur due to an incorrect breaker size.

How do you connect Powermax?

Connecting your Powermax security system is easy. First, locate the wiring terminals on your system. The power supply should already be connected, while the external sounder, telco lines, and additional input/output wires will need to be connected.

Once you’ve connected the wiring, you can use the communications hardware provided with your system and the Step-by-Step Setup Wizard to connect your system to the Telguard website for online monitoring.

After connecting the wiring, you will need to program zone types, control panel settings and user codes. Additionally, if you’re using a wireless system, you will need to register the sensors and alarm keypads to the control panel and assign them to the proper zone.

Once these steps are completed, your Powermax system will be ready for use.

What psi air setting is required for plasma cutting?

The psi (pounds per square inch) of compressed air required for plasma cutting depends on several factors, including the current rating of the plasma torch, the material being cut, the thickness of the material, and the speed or rate of the cut.

For example, for a common 150 amp plasma cuttor, the air pressure for mild steel might range from 45 to 65 psi for a ¼” plate, and from 60 to 70 psi for a ½” plate. For aluminum, the pressure may be lower, ranging from 30 to 50 psi for a ¼” plate and from 40 to 55 psi for a ½” plate.

It is important to note that the speed of the cut will also affect the psi requirements because a slower rate of cutting will generally require lower air pressure to push the molten material away from the cut.

A good rule of thumb is to increase the air pressure by 10 psi for each one inch increase in thickness when plasma cutting different materials at the same current setting. As a general guideline, it is best to start with the lowest psi setting that will produce satisfactory results and then increase the pressure as necessary.

What happens if CFM is too low?

If the cubic feet per minute (CFM) is too low, it can cause several different problems. For instance, lower CFM may mean the air handler is not able to move air through the system quickly enough and can lead to insufficient air circulation in the building.

This can decrease system efficiency and overall air quality. The equipment may also be too noisy and may be underperforming. Additionally, since air flows slower, airborne particles may also collect in the vents, increasing the risk of contamination and leading to poor indoor air quality.

Low CFM can also reduce the effectiveness of the dehumidification process, leading to poor indoor comfort. All of which can cost more money in the long run due to inefficiencies.

How many CFM do I need for 1200 square feet?

When calculating the CFM (Cubic Feet per Minute) necessary for a space, the most important factor is to figure out the total area of the room. For example, if a room is 20 feet long by 20 feet wide, its size would be 400 square feet.

In order to get the CFM required for the room, you would need to calculate the CFM per square feet.

For a living space, it is usually recommended to have a CFM of 5-7. Therefore, if you have a space of 1200 square feet, you would need approximately 6000-8400 CFM (1200 x 5 = 6000 and 1200 x 7 = 8400).

In addition to size, you should also consider the type of room, air removed from the space and any additional features that may impact the CFM. For example, if you have a kitchen, you may need to add additional CFM for a range hood.

Or, if the room has high ceilings, you may need additional CFM to push the air up to the ceiling. These can all impact the amount of CFM your space requires.

In conclusion, for a space of 1200 square feet, you would need approximately 6000-8400 CFM. However, this number may change depending on the factors mentioned above.

What is the maximum wear depth pit you should allow in a copper plasma cutting electrode?

The maximum recommended wear depth pit for a copper plasma cutting electrode is 1/32 of an inch (0. 8 mm), or less. Monitoring the wear pit depth on the electrode is important to ensure efficient cutting performance and prevent premature electrode failure.

Worn electrodes may cause poor cut quality, arc wander, and in certain cases, machine failure due to current spike. The advanced erosion rating on copper power contacts increases when the pit depth is greater than 1/32 of an inch (0.

8 mm). This increase in erosion rating can reduce the service life of the part and cause mechanical failure through excessive wear. Depending on the number of cycles you’re running, and the severity of your plasma cutting application, you may need to replace your electrode before it reaches 1/32 inch as a preventive measure.

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