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| Most of the time, you will not be using ProtoMAX LAYOUT to design a part. Thankfully, this program can accept ".dxf" files, but you still have to create the tool paths. If using a ".dxf" file, import the file to skip the last section and start here to give it a tool path. | | Most of the time, you will not be using ProtoMAX LAYOUT to design a part. Thankfully, this program can accept ".dxf" files, but you still have to create the tool paths. If using a ".dxf" file, import the file to skip the last section and start here to give it a tool path. |
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− | Before showing you how to create a tool path, there are a couple of things that you must keep in mind. When the water jet cuts it has a kerf which means it will take away some of the material it is cutting and you do not want it to be taking material away from your part. Instead, you want to remove material from the scrap that is not critical to the part's function and as a result the tool path must be created with this in mind. To do this, you must first keep in mind that the waterjet will always cut on the left side of the tool path lines. This changes based on the direction the nozzle is traveling; for example if the nozzle travels clockwise around a circle it will remove excess material outside of the circle and if it travels counterclockwise it will remove excess material from the inside of the circle. Because of this, you must control the direction that the nozzle will travel. For an outside cut, you want it to cut on the outside of the line to preserve the proper dimensions of the part. For and inside cut, you want the opposite of that. For a ring, you would want the nozzle to travel clockwise for the outside cut and counter-clockwise for the inside cut. To control the direction of the nozzle, you place lead-in and lead-out lines. Its how you specify the start or end of a cut and the cut direction. Lastly, it is better to cut the inner bits first and then the outer bits last; and if you can help it, don't let the nozzle travel over any holes that were already cut. | + | Before showing you how to create a tool path, there are a couple of things that you must keep in mind. When the water jet cuts it has a kerf which means it will take away some of the material it is cutting and you do not want it to be taking material away from your part. Instead, you want to remove material from the scrap that is not critical to the part's function and as a result the tool path must be created with this in mind. To do this, you must first keep in mind that the waterjet will always cut on the left side of the tool path lines. This changes based on the direction the nozzle is traveling; for example if the nozzle travels clockwise around a circle it will remove excess material outside of the circle and if it travels counterclockwise it will remove excess material from the inside of the circle. Because of this, you must control the direction that the nozzle will travel. For an outside cut, you want it to cut on the outside of the line to preserve the proper dimensions of the part. For and inside cut, you want the opposite of that. For a ring, you would want the nozzle to travel clockwise for the outside cut and counter-clockwise for the inside cut. To control the direction of the nozzle, place lead-in and lead-out lines to specify the start or end of a cut and the cut direction. It is better to cut the inner bits first and then the outer bits last; and don't let the nozzle travel over any holes that are already cut. |
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| # Zoom in closer to the circle. Select the "Lead i/o" tool from the "Draw" menu on the left of the screen. Select the bottom edge of the circle and move the cursor upwards and click to create a lead in and out from the center of the circle. This will tell the water jet to cut on the inside of the circle. Looking at this picture, you can see that one line is longer than the other. This longer line is the lead-in line. The nozzle will penetrate the material from the beginning of the long line and work its way down to the bottom of the circle. Once the nozzle hits the bottom, it will start counter-clockwise because the lead-in line is positioned at a slight angle to make counter-clockwise and easier direction than clockwise. This is how you tell the nozzle which direction to cut.[[File:Lead_i-o.png|none|thumb|600x600px]] | | # Zoom in closer to the circle. Select the "Lead i/o" tool from the "Draw" menu on the left of the screen. Select the bottom edge of the circle and move the cursor upwards and click to create a lead in and out from the center of the circle. This will tell the water jet to cut on the inside of the circle. Looking at this picture, you can see that one line is longer than the other. This longer line is the lead-in line. The nozzle will penetrate the material from the beginning of the long line and work its way down to the bottom of the circle. Once the nozzle hits the bottom, it will start counter-clockwise because the lead-in line is positioned at a slight angle to make counter-clockwise and easier direction than clockwise. This is how you tell the nozzle which direction to cut.[[File:Lead_i-o.png|none|thumb|600x600px]] |
| # Next, place a "Lead i/o" near the bottom of the left wall on the square moving your cursor to the left and clicking to tell the machine to cut on the outside of the box.[[File:Lead_io2.png|none|thumb|600x600px]] | | # Next, place a "Lead i/o" near the bottom of the left wall on the square moving your cursor to the left and clicking to tell the machine to cut on the outside of the box.[[File:Lead_io2.png|none|thumb|600x600px]] |
| # Select the "Line" tool and connect the long, lead-in line of the box to the short, lead-out line of the circle. This is a traverse line telling the machine to move from the circle to the box after it has finished cutting the circle. | | # Select the "Line" tool and connect the long, lead-in line of the box to the short, lead-out line of the circle. This is a traverse line telling the machine to move from the circle to the box after it has finished cutting the circle. |
− | # Use the line tool and click on the long, lead-in line for the circle. Place the other end of the line so that it is at least 1/8" past both the left and bottom edge of the part. This will be the origin for the part and the cut. It should look something like this.[[File:Design_with_traverse_lines.png|none|thumb|600x600px]] | + | # Use the line tool and click on the long, lead-in line for the circle. Place the other end of the line so that it is at least 1/8" past both the left and bottom edge of the part. This will be the origin for the part and the cut. It should look something like this:[[File:Design_with_traverse_lines.png|none|thumb|600x600px]] |
− | # Now you get to decide the quality of each cut. Select the button at the bottom of your screen labeled "Quality". You should see a range from 1 to 5, a Traverse, and Lead i/o. The range of 1 to 5 will change the machines cutting speed. The higher quality is 5 (slower) and the lowest quality is 1 (faster). Choose a quality of 5 for the circle by clicking "5" and then selecting every part of the circle. Do the same for the outer edge but with a quality of 1. Your part should look like this. Leave the traverse lines as green. You don't want them to cut there.[[File:Quality_lines.png|none|thumb|600x600px]] | + | # Now you get to decide the quality of each cut. Select the button at the bottom of your screen labeled "Quality". You should see a range from 1 to 5, a Traverse, and Lead i/o. The range of 1 to 5 will change the machines cutting speed. The higher quality is 5 (slower) and the lowest quality is 1 (faster). Choose a quality of 5 for the circle by clicking "5" and then selecting every part of the circle. Do the same for the outer edge but with a quality of 1. Your part should look like this. Leave the traverse lines as green. This indicates where you don't want the machine to cut. [[File:Quality_lines.png|none|thumb|600x600px]] |
− | # Sometimes there are extra points or lines that are unnecessary. Click "Clean" on the right side of your screen, click "start" on the popup window, and "okay" on the second popup window. Now your tool path is cleaned. | + | # Sometimes there are extra points or lines that are unnecessary. To remove these points, click "Clean", click "start" on the popup window, and "okay" on the second popup window. Doing this will insure a tidier cut |
− | # The last step is saving the file to be cut. Click "Post" on the right of your screen. This may ask you to save your drawing; do so. It will then bring you to a window asking you to "Pick Start". Select end of the traverse line that you defined as the origin. | + | # The last step is saving the file to be cut. Click "Post" on the right of your screen. If you have not saved yet, this will ask you to save your drawing; do so. It will then bring you to a window asking you to "Pick Start". Select end of the traverse line that you defined as the origin. |
| # A window will popup showing the tool path. Zoom in closer to your part and inspect where the tool path is. The program will display cuts as a thick red line. Make sure that these projected cut lines are on the proper side of the line that you specified. If all looks well, hit "save" on the bottom, left of your screen. | | # A window will popup showing the tool path. Zoom in closer to your part and inspect where the tool path is. The program will display cuts as a thick red line. Make sure that these projected cut lines are on the proper side of the line that you specified. If all looks well, hit "save" on the bottom, left of your screen. |
| '''Waterjet Operation :''' | | '''Waterjet Operation :''' |
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| # Open MAKE. | | # Open MAKE. |
| # Zero the water jet cutter head using MAKE. | | # Zero the water jet cutter head using MAKE. |
− | # Push the clear plastic hose into the hole located on the side of the nozzle. This hose is abrasive feed tube and is used to mix the abrasive into the water. | + | # Push the clear plastic hose into the hole located on the side of the nozzle. This hose is called the abrasive feed tube and is used to mix abrasive into the water. |
− | # Position the nozzle between two of the metal ribs, close the lid, and test the nozzle using MAKE. When closing the lid, the support bar on the right side of the lid must be lifted otherwise it will not close. There are two things that should be checked when performing the nozzle test. First, check that the water is flowing through the nozzle. This seems obvious but is necessary because the nozzle can get clogged. Second, check that there is abrasive flowing through plastic tube. It flows quickly but can be identified by a sparkling in the tube as it flows.[[File:Waterjet_clamps.jpg|none|thumb|479x479px]] | + | # Position the nozzle between two of the metal ribs, close the lid, and test the nozzle using MAKE. When closing the lid, the support bar on the right side of the lid must be lifted otherwise it will not close. There are two things that should be checked when performing the nozzle test. First, check that the water is flowing through the nozzle. This is necessary because the nozzle can get clogged. Second, check that there is abrasive flowing through plastic tube. It flows quickly but can be identified by a sparkling in the tube as it flows. |
− | #Open the lid, position the material in the machine, and clamp it down. To clamp down the material, first slip the clamping post into the slot on the crossbar and the twist clockwise to tighten it into place. Then slide the material clamp over the post and push down to tighten. Repeat this process with any other clamps that are needed to secure the material. The clamping system can be seen below. | + | #Open the lid, position the material in the machine, and clamp it down. To clamp down the material, first slip the clamping post into the slot on the crossbar and the twist clockwise to tighten it into place. Then slide the material clamp over the post and push down to tighten. Repeat this process with any other clamps that are needed to secure the material. The clamping system can be seen below.[[File:Waterjet_clamps.jpg|none|thumb|479x479px]] |
| # Load the cut file into MAKE, select the material being cut, and enter its thickness. | | # Load the cut file into MAKE, select the material being cut, and enter its thickness. |
| # Set the origin point for the machine in MAKE. | | # Set the origin point for the machine in MAKE. |
| # Position the nozzle over the material and adjust the height of the nozzle very carefully making sure the adjustment tool has enough room to wiggle up and down. Do this by loosening the knob on the side of the nozzle with one hand while holding the nozzle with the other. Be very careful not to drop the nozzle onto the material as it could be broken. Slide the adjustment tool, pictured below, under the nozzle and then carefully lower the nozzle onto it. Tighten the knob once the nozzle is positioned correctly. | | # Position the nozzle over the material and adjust the height of the nozzle very carefully making sure the adjustment tool has enough room to wiggle up and down. Do this by loosening the knob on the side of the nozzle with one hand while holding the nozzle with the other. Be very careful not to drop the nozzle onto the material as it could be broken. Slide the adjustment tool, pictured below, under the nozzle and then carefully lower the nozzle onto it. Tighten the knob once the nozzle is positioned correctly. |
| # Continue to fill the tank with more water so that there is about 1/8" of water above the surface of the material. | | # Continue to fill the tank with more water so that there is about 1/8" of water above the surface of the material. |
− | # Execute a dry run making sure that the nozzle will not collide with anything. | + | # Execute a dry run using MAKE while ensuring that the nozzle will not collide with anything. |
− | # Flip the orange rubber cone down, run the cut, and watch out for: | + | # Flip the orange rubber cone down, run the cut. While the cut is running look for material excess floating up; pieces of cut material floating up and getting wedged between the nozzle and other material or clamps could cause a catastrophic failure. If you see any of these things, pause the cut and remove any obstructions before resuming. |
− | #* Material excess floating up; pieces of cut material floating up and getting wedged between the nozzle and other material or clamps could cause a catastrophic failure. Pause the cut if you think this may happen.
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| '''Waterjet Shutdown:''' | | '''Waterjet Shutdown:''' |
| # Remove the material and clamps from the work area. | | # Remove the material and clamps from the work area. |
| # Remove the abrasive feed tube from the nozzle. | | # Remove the abrasive feed tube from the nozzle. |
− | # Position the nozzle between two of the metal ribs and run a nozzle test. This clears any remaining abrasive from the nozzle to help prevent clogging. | + | # Position the nozzle between two of the metal ribs and run a nozzle test to clear any remaining abrasive from the nozzle and prevent future clogging |
| # Bring the nozzle back to its home position. | | # Bring the nozzle back to its home position. |
| # Close MAKE. | | # Close MAKE. |
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| # If you see water squirting out the side of the machine while running a cut, don't touch it! It is the fountain of "Bye Bye Fingers." | | # If you see water squirting out the side of the machine while running a cut, don't touch it! It is the fountain of "Bye Bye Fingers." |
| # Wear rubber gloves while dealing with the water in the tank. The water in there is a nasty pool of bacteria and chemicals just waiting to crawl into your open wounds. | | # Wear rubber gloves while dealing with the water in the tank. The water in there is a nasty pool of bacteria and chemicals just waiting to crawl into your open wounds. |
− | # If you're an idiot and manage to run the water jet while your hand is underneath it, you have the opportunity of going to the ER and taking with you a medical card that tells the doctors how to treat you so you don't die. | + | # If you have true "talent" and manage to run the water jet while your hand is underneath it, you have the opportunity of going to the ER and taking with you a medical card that tells the doctors how to treat you so you don't die. |
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| ==Certification== | | ==Certification== |
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| ==Troubleshooting== | | ==Troubleshooting== |
− | There are a few common issues you may run into when using the waterjet. First, there may be an issue reaching the proper water level for your material. This is caused by the drain tube on the right side of the tank being at the incorrect height and can be fixed by pushing the drain tube up or down to remove water or allow more to enter. Make sure to wear gloves when doing this to protect from bacteria and never pull on the tube because it can be pulled off. If the tube does pull off, don't freak out, wait for the water to drain low enough to push the tube back on and then do so. | + | There are a few common issues you may run into when using the waterjet. First, there may be an issue reaching the proper water level for your material. This is caused by the drain tube on the right side of the tank being at the incorrect height and can be fixed by pushing the drain tube up or down to remove water or allow more to enter. Make sure to wear gloves when doing this to protect from bacteria and never pull on the tube because it can be pulled off. If the tube does pull off don't panic; wait for the water to drain low enough to push the tube back on and then do so. |
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− | Another issue is that the abrasive may not be flowing through its tube when performing the nozzle test. If this is happening do not perform a cut until the abrasive if flowing properly. The first thing you should check is the abrasive tube. Make sure that it is completely pushed into the nozzle so that it can be pulled out of the hopper by the vacuum within the nozzle. If this does not fix the issue then there is most likely water in the hose and maybe even in the hopper which causes the abrasive to stick to the feed tube tube instead of flowing through properly. Try removing the hopper splash guard, pull the feed tube out of the feed block, and then use an air hose to blow through the feed to clean out any moisture. These components can be seen in the image below. Sometimes the water will travel into the hopper itself and cause the abrasive to clump together. When this happens either wait a day for everything to dry out or carefully disassemble the hopper system and dry it out with the help of an ACE and the [https://knowledgebase.omax.com/protomax/content/401434/nozzle-clog.htm?tocpath=MANUALS%7COPERATION%20GUIDE%7C_____11 user manual]. | + | Another issue is that the abrasive may not be flowing through its tube when performing the nozzle test. If this is happening do not perform a cut until the abrasive if flowing properly. The first thing you should check is the abrasive tube. Make sure that it is completely pushed into the nozzle so that it can be pulled out of the hopper by the vacuum within the nozzle. If this does not fix the issue then there is most likely water in the hose and maybe even in the hopper which causes the abrasive to stick to the feed tube tube instead of flowing through properly. Remove the hopper splash guard, pull the feed tube out of the feed block, and then use an air hose to blow through the feed to clean out any moisture. These components can be seen in the image below. Sometimes the water will travel into the hopper itself and cause the abrasive to clump together. When this happens either wait a day for everything to dry out or carefully disassemble the hopper system and dry it out with the help of an ACE and the [https://knowledgebase.omax.com/protomax/content/401434/nozzle-clog.htm?tocpath=MANUALS%7COPERATION%20GUIDE%7C_____11 user manual]. |
| [[File:Waterjet_Abrasive.jpg|none|thumb|799x799px]] | | [[File:Waterjet_Abrasive.jpg|none|thumb|799x799px]] |
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− | Often, if there is water in the abrasive feed tube it is caused by the nozzle being clogged. Unclogging the nozzle is a fairly intensive and delicate process and should be done with the help of an ACE. This will cover the overview of the process but make sure to reference the manufacturer's [https://knowledgebase.omax.com/protomax/content/401434/nozzle-clog.htm?tocpath=MANUALS%7COPERATION%20GUIDE%7C_____11 nozzle clog procedure] for the complete process and a video showing it being completed. Before unclogging the nozzle, remove the yellow rubber cone and raise the nozzle as high as it can go while being careful not to let it drop onto the material. | + | Often, if there is water in the abrasive feed tube it is caused by the nozzle being clogged. Unclogging the nozzle is a fairly intensive and delicate process and should be done with the help of an ACE. This will cover the overview of the process but make sure to reference the manufacturer's [https://knowledgebase.omax.com/protomax/content/401434/nozzle-clog.htm?tocpath=MANUALS%7COPERATION%20GUIDE%7C_____11 nozzle clog procedure] for the complete process and a video showing it being completed. Before unclogging the nozzle, remove the yellow rubber cone and raise the nozzle as high as it can go while being careful not to let it drop onto the material. [[File:Waterjet_Nozzle.jpg|none|thumb|496x496px]] |
− | #[[File:Waterjet_Nozzle.jpg|none|thumb|496x496px]]Once this is done, use the included torque wrench to loosen the set screw holding the mixing tube (1) in place. Make sure to hold onto the tube when doing this so it does not drop out.
| + | #Once this is done, use the included torque wrench to loosen the set screw holding the mixing tube (1) in place. Make sure to hold onto the tube when doing this so it does not drop out. |
| # Remove the tube and reinsert it upside down so that the pointed end is facing upward. | | # Remove the tube and reinsert it upside down so that the pointed end is facing upward. |
| # Very carefully tighten the set screw to 15 in-lb using the torque wrench. The torque wrench will click when 15 in-lb is reached but it is very faint so tighten slowly or the entire tube will be crushed. | | # Very carefully tighten the set screw to 15 in-lb using the torque wrench. The torque wrench will click when 15 in-lb is reached but it is very faint so tighten slowly or the entire tube will be crushed. |