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disney infinity 2 0 creator guideTraining We offer standard and bespoke training courses. Technical support library Find supporting documentation for your Renishaw products. Software Manage your software licensing and discover more about software agreements. MyRenishaw Manage your account or register your products. News News Latest company and product news. Media hub Images, video and text approved for use by media organisations. Events See live demonstrations of Renishaw's latest products at events around the world. Social media and online presence Online channels designed to make our customers' lives easier. Investor relations news The latest news for investors. Register for news updates Select the types of news you would like to receive. Our company Learn more about Renishaw Renishaw is a global company with core skills in measurement, motion control, spectroscopy and precision machining. Corporate social responsibility Details of our business code, charities committee and our statement about modern slavery. Media hub Images, video and text approved for use by media organisations. Events and webinars See live demonstrations of Renishaw's latest products at events around the world. Investor relations Information for shareholders and prospective investors. News News for the metalworking, metrology, toolmaking, automation and motion control industries. Careers Learn more about working at Renishaw and view current vacancies. Worldwide offices We have offices in 37 countries around the globe. Find the right office to meet your needs. Supplier portal Information for suppliers, or potential suppliers, to Renishaw. A MyRenishaw account will give you quick access to additional content on this site and enable you to manage your preferences. Low-risk investment for fast payback. Exceptional ease of use. Outstanding performance for increased yield and shorter cycle times.http://ntg-holdings.com/pic/excalibur-dehydrator-owners-manual.xml

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Working on a 5-axis machine minimizes setups, allows for faster cycle time, produces less scrap, and increases spindle up time, giving your shop the ability to open its possibilities. Discover the GENOS M560-V today View operating history and production rates in visual graph format and see alarm history with live links to alarm details, all on an easy-to-read display. Okuma is pleased to offer 10 off power supply units! In the beginning they were hand-drawn electrical drawings on tracing paper that were blueprinted, and the operator’s manuals were typed on an actual typewriter. Hence we provided hard copies only. Then the computer age came, and the drawings were created in CAD format and the manuals typed in a word processor program. These manual files were considered huge at the time, so hard copies were still provided. By the time of the E100 control we entered the CD age and all the manuals were provided as hard copies and on CDs. Today, thanks to all the technological changes in the P300A control, the manuals are provided on DVD and loaded directly onto each machine. Okuma and our distributors feel it’s much more important to take the time to review what your machine has from the factory, as well as the optional features you have purchased, and provide you with manuals that specifically cover what you’re using. Okuma and distributors have support people ready and able to get you either electronic copies, DVDs or hard copies of any manual for your machine tool. When you request a manual we also like to take the time to make sure you’re getting the manual that will answer your question best and not require you to figure out which manual has what information and if a generic manual post online will fit your machine. Here are some of the most common types you can request: From changing the fluids, to which parts should be replaced for preventive maintenance. Feel free to leave a comment below.http://www.justaskislam.com/files/excalibur-digital-compass-manual.xml Fill out the form below to let us know the type of information you'd like to receive. Fill out the form below to let us know the type of information you'd like to receive. Be aware that they do not cover all possible hazards. Precautions Relating to Installation (1) Please be noted about a primary power supply as follows. Inspect the following points every three months. Read the instructions marked with these symbols carefully and follow them. DANGER indicates an imminently hazardous situation which, if not avoided, will result in death or serious injury. Before using this NC unit (hereafter simply called NC), thoroughly read this programming manual (hereafter called this manual) in order to ensure correct use. This manual explains how to use and maintain the NC so that it will deliver its full performance and maintain accuracy over a long term. Functions such as a sequence search function, a sequence stop function and a branching function can be used for blocks assigned a sequence name. A table of the operation symbols is shown below. Operation functions can be used together with variables to control peripherals or to pass on the results of an operation. Category Operation Operator. For execution, a program is transferred from the memory to the operation buffer (RAM). Address Contents Controlled axis in the direction parallel to the workpiece end face Linear axis Controlled axis in the direction parallel to the workpiece longitudinal direction. Even if dimensions are specified in the inch system values in a part program, the NC processes the data on the basis of metric system values. Due to the nature of the turning operation, the tool cuts a circle with a radius equivalent to the distance from the center of rotation to the tool nose position. Although such chamfering can be accomplished using conventional interpolation commands (G01, G02, G03), the automatic chamfering function permits chamfering to be done with a simple program. To avoid this, set the torque monitoring delay time t for a parameter. The programmable range for M codes is from 0 to 511. By specifying M110, the spindle is controlled in the C-axis control mode and by specifying M109, the control mode is returned to the spindle control mode. M-tool Spindle Commands 5-1. Code Details Used to designate the spindle to be controlled in the C-axis control mode. M110 When programming C-axis commands, first specify M110 in a block without other commands. Continued from turning operation program Indexes C-axis in the positive direction.With the tool radius compensation function, such geometric error is automatically compensated for by simple programming. G Codes G40: Used to cancel the tool nose radius compensation mode. G41: Tool nose radius compensation - Left Used when the tool moves on the left side of the workpiece. While the positioning command from point A to point B is being executed, the positioning point data of points C, D and E are read and stored in the buffer. This is called the 3-buffer function. Since such compensation is performed automatically, there are some restrictions in programming when the tool nose radius compensation function is used. In addition, because X words are expressed as diameters, the X word data has to be doubled. That is, the numerical value in such an X word must be larger than four times the tool nose R. Other axis motions of the cutting tool are identical to those for cutting an arc in two quadrants. The tool path is generated so that the tool nose R is brought into contact with each arc or its extension. If a switch-over is to be done with the compensation mode active, carefully check the movement of the cutting tool resulting from the switch-over. It is essential to understand the cutting tool movements that result from the cancelation of the compensation mode in order to avoid unexpected trouble. Positioning fort programmed point N3 is carried out at the point where the tool nose R comes into contact with point N3, and that for programmed point N4 is carried out at point O4; the same point reached by the program in which the tool nose radius compensation function is not activated. From N3 to N31, the positioning is on the right hand side of the line. Commands in block N32 position the cutting tool at the point where the tool nose R is brought into contact with straight lines N31 - N32 and N3 - N4 on the right side of the direction of tool advance. Therefore, axis behavior can be easily expected if only these respective sides are longer than twice the tool nose R (four times on the X-axis). Using this function, cutters of different diameters can be used to machine workpieces of the same shape without modifying the program. In the G101, G102, and G103 modes, the direction of rotation is automatically determined by the control. The X-axis returns to the thread cutting cycle starting point. The Z-axis returns to the thread cutting cycle starting point. For G33 cycle: First thread Second thread Start point for the first thread Start point for the second thread LE33013R0300900060010 Thread cutting is carried out by shifting the thread phase by the amount (angle) specified by the. The correspondence between modes and M codes is as follows: M32: Straight infeed along thread face (on left face) M33: Zigzag infeed M34: Straight infeed along thread face (on right face) When none of these M codes is specified, the control automatically selects the M32 mode. In each odd numbered tool paths, the cutting point is calculated as;. In the compound fixed thread cutting cycle, multi-thread cutting can be designated by simply designating the number of threads with a Q command. Specify this G code immediately after a sequence number (name). An M code is given priority over the optional parameter setting.When M141 (C-axis clamp ineffective) is designated, C-axis clamp motion is eliminated, resulting in a reduced cycle time. After the completion of positioning, the M-tool spindle starts rotating in the forward direction. After the completion of positioning, the M-tool spindle starts rotating in the forward direction. Axis motion is suspended at point Z until the M-tool spindle and the Z-axis come within the droop. LE33013R0300900460001 The repeat function allows repeated designation in two blocks. Note that the repeat function is effective for G178, G179 and G181 through G184 and G189, G190 cycles. If R27 were specified instead of R-27 in the program above, the direction of the drilling cycle would be as indicated below. However, using the M-tool spindle interlock release M code in the optional operation time reduction function allows rotation of the M-tool even if the C-axis is not in the joined state. D word: peck feed stroke (mm) E word: duration of dwell motion (seconds) In the program shown above, peck feed in 10 mm increments (diameter value) is repeated until the programmed depth is reached, where dwell motion is executed for one second. Continued from turning operation program After the end mill is positioned to X95 at the rapid feedrate, it starts rotating. With this function, the control automatically generates a tool path to produce the required part contour. Longitudinal Mode Transverse Mode e II. The cutting tool moves at the rapid feedrate in other areas. G Codes G Code Description End of contour definition Start of contour definition, longitudinal Start of contour definition, transverse Start of blank shape definition (LAP4 only) Change of rough turning conditions, bar turning Bar turning rough turning cycle. Sequence name in the first block of contour defining blocks G code calling out copy turning cycle To be designated right after sequence number (name). Sequence name in the first block of contour defining blocks G code calling out finish turning cycle To be designated right after sequence number (name). AP Modes AP modes I through V are explained here.A rough turning cycle in the bar turning mode is performed with this program. The feedrate in this cutting cycle is the one selected by the F word when the rough turning cycle was called out. The Z-axis returns to Zp as determined in step (4) at the rapid feedrate and then the X axis returns to Xp. Z-axis return A ( Zp, Xp ) ( Za, Xa ) LE33013R0301000140004. The Z-axis then returns to the point where cutting along the X-axis was started in the G01 mode in step (10). After the completion of Z- axis positioning, the X-axis is positioned at the point where the previous cutting cycle was started. When this level is reached, the final rough turning is carried out along the contour up to point B. The new XOFF and ZOFF are calculated and steps (4) through (6) are repeated.This eliminates unnecessary tool motion which is generated when the same tool is used in the next machining process. To change the cutting conditions during the rough turning cycle, designate the following commands with G84. The feedrate in this cutting cycle is as selected by the F word when the rough turning cycle is called out. The Z-axis returns to the next infeed point at the rapid feedrate and then the X-axis to Xs.After that point, the same cycle is repeated with the depth of cut (D) and feedrate (F) changed.There are two patterns of axis return motion: The two axes return to the AP starting point simultaneously when G00 is designated in the first block of the contour definition program (the block following the one containing either G81 or G82). AP starting point (Zs, Xs) Blank material shape Workpiece shape after the tool nose radius. The blank material shape is programmed in the blocks starting with G83. Cutting is parallel to the designated blank material shape. The cutting tool is then positioned at the next infeed starting point B at the rapid feedrate.In such cases, define the shape again or divide the machining process. Cutting direction Blank material shape End point. Correct the program as necessary, for example, change the AP starting point. From AP Mode IV to AP Mode I AP starting point AP starting point In AP Mode IV In AP Mode I. Otherwise, the cutting tool interferes with the workpiece. From AP Mode V to AP Mode II In AP Mode V In AP Mode II. Note that simultaneous three-axis control of X, Z, and C axes is possible for straight line cutting on a plane. Programming is performed on the plane which is obtained by developing the cylindrical surface. Although G119 is originally used for the designation of the Z-C plane as the offset plane in the nose R compensation mode, it is also used to call out the side contour generation programming mode when this function is used. This function simplifies programming when a hole on the end face of a workpiece is not specified by the angle but by the vertical distance from a radius vector. Programming 1-1. That is, N0101 directly follows N0049 and N0151 follows N0099. Therefore, when the S, T, and M commands in these blocks are the same as designated in N0001 and N0051, respectively, they can be omitted. This means that simultaneous 4-axis cut yields nearly a 48 saving on cutting time. The stored subprogram can be accessed from the main program by specifying the program name, which represents a group of instructions, and the operations and functions in that program can be executed. Of these, the GOTO statement and the IF statement are User Task 1 functions. Up to 127 local variables each can be used for the A and B saddles. The local variables set in the block containing the CALL statement are all cleared when the RTS statement in the called subprogram is executed. They are effective only in the subprogram in which they are set, and are cleared when the RTS statement in that subprogram is executed. The system variables are not cleared when the control is reset.Screen display 2288 Alarm B User reserve code. Executing the RTS block ends the called subprogram and the execution sequence jumps to the block right after the one containing the CALL statement. The subprogram is executed from N001 and when the control reads the RTS statement in N050, sequence execution then jumps back to N1001 of the main program and the commands in that block and subsequent blocks are executed. Example: Two nesting levels Main Program Subprogram O1000 N001 MODIN O1000 N1001 N010 MODIN O2000 N1010 N011 N012 O2000 N2001 N020. PUT statement: This stores the numerical data and character string of the set variable in the write area output by the WRITE statement. External READ Common variable device, Read area System Puncher, variable Local Printer, WRITE variable etc.When variables are set in a block preceding the one where the sequence return is executed, the set data are all registered in the memory. Please refer to these examples and the programming methods used so that you can make the most of the User Task function. The points that must be calculated are Z-coordinate of point a and X- and Z-coordinates of point b. To simplify the programs of these pulleys, express the contour of part A using variables. Variable Numerical Value for Contents Name. Using this subprogram, the program to cut the pulley shown in Fig. 3-1 can be prepared.The function also searches a specified subprogram file, or system subprogram file, and manufacturer subprogram file for the required subprograms and selects them automatically. Assume that the NC lathe is equipped with a bar feeder and three different workpieces are machined according to the programmed schedule. However, by using this feature the command is given simply by entering either the X or Z coordinate point of the end point of the taper along with the angle referenced to the Z-axis (measured in the counterclockwise direction). It is positive when measured in the counterclockwise direction and negative in the clockwise direction. In the figure below, the angle is expressed as A135 in 1 mm unit system control since the angle is measured in the counterclockwise direction. Turret Unclamp Command (for NC Turret Specification) The NC simultaneously unclamps the turret and causes axis travel on receiving the M203 command. Be careful of this matter sufficiently when you give a command. Please also note that specifications are subject to change without notice. If you require clarification or further explanation of any point in this manual, please contact your OKUMA representative. To start viewing messages,Like Meau site they have all manual. Thank you! Similar Threads: Okuma-Howa 3VA manual(s) Okuma parameters manual I need IGF manual or pdf for okuma LB15 Anyone have a manual for a 250psi Okuma TSC pump for Okuma Mill? Like Meau site they have all manual. Thank you! I can probably send you a copy of what you need. I am short of time, I have to go to work, I can send you the document tomorrow.Best regards Rogy10 If I had a problem then I ask you. Darek You need to look at Scribd too. The site is 100 free to join and use, so join today! Working on a 5-axis machine minimizes setups, allows for faster cycle time, produces less scrap, and increases spindle up time, giving your shop the ability to open its possibilities. Discover the GENOS M560-V today View operating history and production rates in visual graph format and see alarm history with live links to alarm details, all on an easy-to-read display. Okuma is pleased to offer 10 off power supply units! There are several new technologies that should be on your hot list if you want to make your life easier, more productive and more efficient. Try them out and you’ll see these functions are addictive (in a good way). This prevents the operator from having to stop the program, search for the point where he left off in the program and “re-start” operation. (But the OSP can still do that). Because of the absolute position encoders on all of our motors, the OSP CNC control always knows where the ATC and APC are, so recovering from an E-stop, power outage or reset are as simple as pressing a button. Can also exit the editor, save the program and select the program for automatic operation with one button. This gives the operator the ability to change the code, look at upcoming code, and then save the changes that were just made. Often times, with large part programs such as those used when making die-mold parts or 5 axis parts, the programs are split up by tool number. This makes the smaller programs more manageable because it can cut down on the file sizes (although we can still run up to a 2GB program in our “Large Program Capacity” mode). Okuma offers many more as standard. The OSP also includes peck tapping as a standard option. It can be used by either counting the number of times the tool is used, or by a cutting time value. It has the added capability of calling up a spare tool and continuing operation without interruption. For more critical parts the parameters will be tightened up and thus provide smoother machine motion and optimum quality parts. If an alarm pops up, the same button will bring up a description of the alarm and possible causes. Comment below and share your thoughts, or contact us or your local distributor and we’ll set up an in-person demo to show you how to make the most of your CNC control. Thank you in advance. Our experts are always available to assist the distributors as they work through any difficult issues as well. I?m develop a post processor for a customer but I have some problems when I work with the 4th axis. I hope that you can help me. Thank u. We?ll keep in touch. I need to be able to comp a few more thous on my tool geometry, but am getting an alarm 2255 6. My question being how or what do I need to adjust, parameter. Thank you! Is it possible? We have a deviceNET-Ethernet gateway module (MAC ID 60) and we want to activate an output from the part program for robot integration. How can we write these outputs? Thank you. Have you tried contacting your local Okuma distributor. They are your first line of defense when it comes to all things related to troubleshooting. If you are unsure who your distributor is, you can find their information here: Okuma Web Team I can start my program and all my user variables are correct. It runs through the probing cycle, but as soon as it's done with the last part as its dwelling, it changes all the variables to something totally different. I can change one of the variables back to the original number, restart the program to the facemill part of the program and all the other variables change back to the original variables, and runs fine until it reaches the end of the probing cycle, where it does it all over again. Any help would be appreciated. Thanks in advance. Jay, osp p300 With the holidays, Paul is out of the office until 2018. We don't want you to wait that long for an answer, so we encourage you to get in touch with your Okuma distributor if you haven't already. If you don't know who that is, you can search for their information on our site: Okuma Web Team My post is outputs the following code and i am using a tap in a ER collet in a live tool holder, tapping on the side of a nut. This code looks to tap in correct but appears to rapid out breaking the tap. So is the code missing something or is there a parameter that makes it work.Your question is a little more than can be answered here. Have you contacted your local Okuma distributor for assistance. Based on the information that you have provided, I believe it would be: Gosiger Indiana 4627 Independence Square Indianapolis, IN 46203 317-788-1501 Thanks. We are having a problem using Y offsets on turning tools. For example using a Y offset to dial a center drill to spindle centerline. When the process is complete it is programed to return to X limit in order to tool change. At this point the machine gets hung up on the next block (tool change) because it is not returning to Y 0. No alarms. I understand using the offset call out ( for example T0012 for tool 12)cancels the original offsets, but it also causes the machine to make an unnecessary position change in X and Z. (The value of the tool offsets) is there a better way. Thank you, Jon Bomba CNC lathe operator Urschel Laboratories Chesterton, IN Within a month I will take a course to get to know my car better. However I would like to create macros but I do not know how to do it. Can you explain briefly how to do it? Thank you Do you have program example.I am trying to learn the Okuma control panel but you use pictures on the keys for which leaves very little information of what they are. I don't understand why you don't just use simple words to list the keys. Just about everyone new to Okuma controls can't identify the function of a key because it is a picture symbol. Do you have a list of those graphic symbols identifying the functions. Much appreciated if you can help. Thanks, Aidan Have OMP40 spindle touch probes and TS27R touchsetters. I wrote my own routine using the skip function. After executing this command the tool life timers quit working. Can't find anything in my manuals on what devices are tied to various VNCOM settings. Can you provide any additional details? Thanks It has a 60 tool belt with random return atc. What im wondering is if their is a way to specify certain or all tools to return to original pot. As in t1 to p1 and so on. Alot of our jobs use alot of the same tooling and we would like to keep about 30 permanent tools in machine at all times. If i use the back door of machine to change tools i have no way of knowing which tools are permanent and which arent currently unless i write them down from tool screen before time. Any assistance in this would be greatly appreciated. Is there a way to broach off the tool change position? Thank you!! Have you contacted your local Okuma distributor. They should be able to assist you with any questions you might have regarding your Okuma machine and accessories. If you don't know who your distributor is, you can find them here: Thanks, Mindy Mikami Web Manager Okuma America Corporation This will display all of the parameter pages. Hope this helps. Paul Russell Sr. Applications Engineer Okuma America COrporation I'd like to know if is it possible to use to measure cutting tools.I have spoken with our application engineering department, and they tell me that if you are still having trouble with the programming for your Renishaw probe, it will be best to contact Renishaw. Alternately, you can contact your local Okuma distributor. If you don't know who that is, you can find that information here: Thanks, Mindy Mikami Web Manager Thank-you, John Fritsch Can anyone help me out. Thanks in advances! You can find your distributor's information here: Mindy Mikami Web Manager My recommendation is to contact you local distributor and have one of their Service Technicians come in and take a look at what is happening. Paul Russell Applications Engineer Okuma America Corporation I'd like to know how to solve this problem. I've been looking for troubleshooting and I found that is possible with a G429 command but only for MU 500 machines. Thanks in advance!! Erik ACOSTA How would I program the spindle to jog with chuck open to let the turret do a chip washout? How do I operate the parts counter? I would like to run the program continuously (not having to keep pressing start every part as it is set up currently) and have it count parts. Any help would be appreciated. Thank you, Ken The operator needs to remember to either zero out the work offset first or call up a dummy offset like G15H0. If the operator does not do this, they will CRASH the machine. Big oversight on Okuma. Work offsets are designed to be ever changing in the shop. They should never be used for tool length calculations. I've never written one and I'm curious as to where and how to get started. Thanks in advance!! We have a new product that requires multiple oval features at different orientations. Thank you in advance for your help. Regards, Dave Can you please tell me what school you are attending so that we can provide you with the proper resources to answer your questions. Support for Okuma machines is normally provided via the local Okuma distributor, so we would like to connect you with them. Thanks, Mindy Mikami Marketing Coordinator Okuma America Corporation Is there a document talking about this specific parameter. Please help me! I am an university student studying in the field of CNC machining. My professor gave me this question and I exhausted all my resource and I couldn't find an answer. Thanks in advance. Steph Our territory is the Americas, so it will be best if you work with your local Okuma distributor in Bulgaria. You can find more information about them by visiting Thanks, Mindy Mikami Marketing Coordinator Okuma America Corporation If these machines have moved from China to the U.S., please work with your local Okuma distributor to troubleshoot your issues.These came from our China facility, which only understand metric. We are trying to find out the tapping format for them, but have no successful attempt. Can you please help.