From f4942eaaad3f52e061790796c134e8a18af443fd Mon Sep 17 00:00:00 2001 From: Luca Toniolo Date: Thu, 16 Jan 2025 12:46:17 +0800 Subject: [PATCH] other capitalizations fixes --- AitalMAC-UI.md | 556 ++++++++++++++++++++++++------------------------- 1 file changed, 278 insertions(+), 278 deletions(-) diff --git a/AitalMAC-UI.md b/AitalMAC-UI.md index 81cc9a4..86a3e15 100644 --- a/AitalMAC-UI.md +++ b/AitalMAC-UI.md @@ -1,4 +1,4 @@ -# 1 Aitalmac UI +# 1 AitalMAC Ui ![AitalMAC UI](/aitalmac-ui/1.png) ***Figure 1**: The AitalMAC application User Interface as it's displayed before connecting* @@ -495,11 +495,11 @@ The stone thickness is utilized in both manual and semi-automatic functions. It The Spindle tab provides direct controls for testing the spindle independently of tool setup. These controls are intended for diagnostic purposes. -#### 1.2.2.1 STOP +#### 1.2.2.1 Stop Halts the spindle immediately, regardless of how it was started. -#### 1.2.2.2 CW (clockwise) +#### 1.2.2.2 CW (ClockWise) Enables the spindle to rotate clockwise, which is the standard rotation direction for AitalMAC machines. @@ -575,65 +575,65 @@ All subsequent manual and semi-automatic functions that utilize the blade automa The button for checking the length of the installed milling cutter is located on the machine. After checking, the actual length of the cutter will be recorded in the tool parameters, and the machine will execute commands with the necessary adjustments. This ensures that the depth of immersion into the worktable and the beginning of milling are accurate, based on the thickness of the material being processed. This helps to avoid collisions and incorrect cuts, as well as any collisions with the material being machined. -#### 1.2.4.6 PROBE STONE +#### 1.2.4.6 Probe Stone Button for using a probe to study the thickness of the material to adjust the operation of the machine according to the program and in manual mode. A button to check the thickness of the material used. Thickness adjustment is necessary for proper cutting with a blade and a water jet at an angle from 1° to 57° in order to maintain the overall dimensions of the part. For milling, this is the redefinition of the safety zone and the calculation of the material milling steps. -#### 1.2.4.7 SLAB WASH +#### 1.2.4.7 Slab Wash Turning on the watering can to clean the material from dirt A button to turn on the water pressure cleaning system. This is necessary to use a vacuum lift for flat material weighing up to 500 kg. Before using the vacuum suction cups, the operator washes the contact points of the suction cups with the material. -#### 1.2.4.8 VACUUM PUMP +#### 1.2.4.8 Vacuum Pump A button to turn on the vacuum pump. When the pump is turned on, a suction force is created on the suction cups to lift and then move the material. -#### 1.2.4.9 LASER +#### 1.2.4.9 Laser The laser line corresponds to the direction of the cutting blade and helps the operator to adjust the cutter to cut the material at the desired location. -### 1.2.5 OUTPUT +### 1.2.5 Output ![1.2.5.png](/aitalmac-ui/1.2.5.png) A tab with output signals for various machine functions. The operator can use these signals to check and adjust settings. -#### 1.2.5.1 CLAMP (Lock Tool) +#### 1.2.5.1 Clamp (lock Tool) Button for fixing the tool clamp (for spindles with automatic changer) -#### 1.2.5.2 INT WATER +#### 1.2.5.2 Int Water Turning on the water to cool the tool through the central hole. Water is supplied through the center of the spindle with air supply to clean the tube after the water is turned off. When turned on, the operator can adjust the air pressure for the required balance. -#### 1.2.5.3 FLUSH +#### 1.2.5.3 Flush Button for cleaning the tool clamp (for spindles with automatic changer) -#### 1.2.5.4 FLOOD +#### 1.2.5.4 Flood Turning on all instrument cooling systems: these are the internal and external cooling supplies. They help the operator to adjust the cooling direction of the tool to produce high-quality work and results. -#### 1.2.5.5 COVER +#### 1.2.5.5 Cover ??? -### 1.2.6 JOINT +### 1.2.6 Joint ![1.2.6.png](/aitalmac-ui/1.2.6.png) The servomotor control tab allows you to exceed the limits in case of an error or if the operator needs to control each axis of the machine individually. -#### 1.2.6.1 JOINT NUMBER (x) +#### 1.2.6.1 Joint Number (X) When clicked, a tab will open with a selection of the servo motor to control. In the case of the Y-axis, the movement must be carried out with extreme care, because the Y-axis controls two servomotors. -#### 1.2.6.2 HOME SELECTED +#### 1.2.6.2 Home Selected A button that will move the axes back to their home position based on the parameters set in the machine, using axis position limit sensors. @@ -645,7 +645,7 @@ A button to move the selected machine axis in the negative direction. Move with A button to move the selected machine axis in a positive direction. Move with a small feed and be careful. -### 1.2.7 CONTROL +### 1.2.7 Control ![1.2.7.png](/aitalmac-ui/1.2.7.png) The operator's manual controls the machine. The operator can adjust the position of the selected cutting tool and perform necessary cutting operations. It is important to raise the work table for convenient loading of processed material and lower it with the material for further work. The operator has access to vacuum suction cups to move the material manually. There is an ability to return the C and B axes to their home positions after moving them manually. @@ -699,288 +699,288 @@ Controlling the tilt of the water jet module along the coordinate axes in the se Controlling the tilt of the water jet module along the coordinate axes in the selected direction. -#### 1.2.7.13 TABLE UP +#### 1.2.7.13 Table Up A button to raise the desktop. The hydraulic pump is turned on and the distribution valve directs the oil into the cylinders to start the lifting mechanism of the worktable. -#### 1.2.7.14 TABLE STOP +#### 1.2.7.14 Table Stop A button to stop the operation of the lifting and lowering mechanism of the desktop. After pressing, the hydraulic pump turns off and the hydraulic distributor switches to the neutral position. -#### 1.2.7.15 TABLE DOWN +#### 1.2.7.15 Table Down The button for lowering the desktop. The hydraulic pump is turned on and the distribution valve directs the oil into the cylinders to start the lowering mechanism of the working table. -#### 1.2.7.16 VACUUM UP +#### 1.2.7.16 Vacuum Up The operator uses a button to activate the vacuum suction cups to move the material. Once activated, the system lowers the vacuum suction cups into their working position using pneumatic cylinders. To visualize the operation, a photo of the material on the desktop is displayed on the screen. This allows the user to see where the suction cups are relative to the material and the table. Depending on the vacuum generation system in use, the vacuum pump or air supply to the vacuum generators may be turned on. Material movement operations should be carried out with a low rate of movement along the desired axes. -#### 1.2.7.17 VACUUM DOWN +#### 1.2.7.17 Vacuum Down The button is necessary for the operator to put the lifted object in the moved place on the desktop. After pressing, the machine will automatically lower the material onto the worktable, the vacuum generation system will turn off, this is turning off the vacuum pump or turning off the air supply to the vacuum generators. The machine will lower the material and raise the vacuum system to standby mode using pneumatic cylinders. -#### 1.2.7.18 ZERO B +#### 1.2.7.18 Zero B After pressing this button, the machine will move along the selected axis B to the position sensor and return to the starting position relative to the set parameters. -#### 1.2.7.19 ZERO C +#### 1.2.7.19 Zero C After pressing this button, the machine will move along the selected axis C to the position sensor and return to the starting position relative to the set parameters. -## 1.3 AUTO +## 1.3 Auto ![1.3.png](/aitalmac-ui/1.3.png) This tab displays the main built-in tabs for writing automatic control programs. Programs can be downloaded from a previously written program or you can create a control program directly on the machine using your own data for cutting and milling. -### 1.3.1 G CODE +### 1.3.1 G Code ![1.3.1.png](/aitalmac-ui/1.3.1.png) This tab opens a window to download the program written for the machine in the Pegasus software. The window contains the main controls and shows the progress of the downloaded program when it is being executed. -#### 1.3.1.1 BLOCK +#### 1.3.1.1 Block This is a block of machine actions according to a written program divided by the number of control commands required for the machine. -#### 1.3.1.2 HEADER +#### 1.3.1.2 Header -#### 1.3.1.3 CODE +#### 1.3.1.3 Code This window displays programs in the form of G codes. Here you can view the actions of the machine when executing the program. The window displays data that can be useful for the operator and the machine operation before starting the program. -#### 1.3.1.4 INFO +#### 1.3.1.4 Info The line displays the command that the machine is currently executing. -#### 1.3.1.5 OPEN +#### 1.3.1.5 Open The button opens a folder with written programs for the machine. In this folder, the operator must select the necessary program to perform the work in automatic mode. -#### 1.3.1.6 RELOAD +#### 1.3.1.6 Reload With this button, the operator can resume the previously selected program. This is necessary if any changes have been made to the program and it was saved with the same name. The machine will simply update the data for this program. -#### 1.3.1.7 SET START +#### 1.3.1.7 Set Start With this button, the operator can select any line in the Block window and the machine will execute programs from this location. To do this, you must first select the desired program line and press Set start. A green marker should appear on this line, which means that the operator has chosen to start the program from the specified location. -#### 1.3.1.8 CLEAN +#### 1.3.1.8 Clean The button is necessary to clear the machine's memory of the downloaded program. Deletes it from the display block, but does not delete it from the folder with written programs. -#### 1.3.1.9 START +#### 1.3.1.9 Start A button to start the execution of the downloaded program. The program will start running from the very beginning or from the location selected by the operator. The machine will execute all commands that are written according to the program, measuring the diameter or length of the tool, checking the name of the tools. It will move to the required location, turn on the spindle and cooling, and start working. -#### 1.3.1.10 STOP +#### 1.3.1.10 Stop A button to stop the program at the current time. The machine will stop in any position and at any time during the execution of the program. All devices used for operation will stop working. Stopping the movement along the axes, turning off the spindle and cooling the tool. On the Block tab, the operator will see the stop step. It will be marked with a green marker. -### 1.3.2 X CUT +### 1.3.2 X Cut ![1.3.2.png](/aitalmac-ui/1.3.2.png) A button to open the menu to create a program for automatic cutting of the material. The operator has the option to use the built-in compiler to create simple programs. For linear cuts along the X-axis. The icon shows the program execution diagram, from right to left and up. This function is used with a cutting disc. It is convenient for cutting the material into identical strips. -#### 1.3.2.1 X-CUT LENGTH +#### 1.3.2.1 X-Cut Length In the line, you must specify the length of the cut to be performed. The starting point of the cut will occur from the actual position of the cutting tool of the machine above the material. -#### 1.3.2.2 X-CUT WIDTH +#### 1.3.2.2 X-Cut Width The line must specify the width of the required cut-out part. After executing the length-cutting command, the machine will rise to a safe height and move to the starting point along the X-axis and offset along the Y-axis with the distance indicated in the row. -#### 1.3.2.3 X-CUT COUNT +#### 1.3.2.3 X-Cut Count The number of parts that need to be made must be specified in the line. This will be the number of repetitions of the first two commands to execute the program. -#### 1.3.2.4 GENERATE +#### 1.3.2.4 Generate A button for creating a control program to perform tasks based on previously entered cutting parameters. After clicking, the operator will be able to see the program G-code and visualization on the screen in the upper right corner. -#### 1.3.2.5 EXIT +#### 1.3.2.5 Exit Exit the menu without creating and saving a program for cutting the material. Return to the previous menu. -### 1.3.3 X&Y CUT +### 1.3.3 X&Y Cut ![1.3.3.png](/aitalmac-ui/1.3.3.png) A button to open the menu to create a program for automatic cutting of the material. The operator has the option to use the built-in compiler to create simple programs. For linear cuts along the X and Y axes, the program execution diagram is shown on the icon, from right to left and up. This function is used with a cutting disc. A cross laser is used as the starting point for creating the program. To cut along the Y axis, the machine head will be rotated 90° along the C axis. It is convenient for cutting the material into identical squares or rectangles. -#### 1.3.3.1 X-CUT LENGTH +#### 1.3.3.1 X-Cut Length In the line, you must specify the length of the cut to be performed. The starting point of the cut will be the position of the laser cross. -#### 1.3.3.2 X-CUT WIDTH +#### 1.3.3.2 X-Cut Width The line must specify the width of the required cut-out part. After executing the length-cutting command, the machine will rise to a safe height and move to the starting point along the X-axis and offset along the Y-axis with the distance indicated in the row. -#### 1.3.3.3 X-CUT COUNT +#### 1.3.3.3 X-Cut Count The number of parts that need to be made must be specified in the line. This will be the number of repetitions of the first two commands to execute the program. -#### 1.3.3.4 Y-CUT LENGTH +#### 1.3.3.4 Y-Cut Length In the line, you must specify the length of the cut to be performed. The starting point of the cut will be the position of the laser cross. -#### 1.3.3.5 Y-CUT WIDTH +#### 1.3.3.5 Y-Cut Width The line must specify the width of the required cut-out part. After executing the length-cutting command, the machine will rise to a safe height and move to the starting point along the X-axis and offset along the Y-axis with the distance indicated in the row. -#### 1.3.3.6 Y-CUT COUNT +#### 1.3.3.6 Y-Cut Count The number of parts that need to be made must be specified in the line. This will be the number of repetitions of the first two commands to execute the program. -#### 1.3.3.7 GENERATE +#### 1.3.3.7 Generate A button for creating a control program to perform tasks based on previously entered cutting parameters. After clicking, the operator will be able to see the program G-code and visualization on the screen in the upper right corner. -#### 1.3.3.8 EXIT +#### 1.3.3.8 Exit Exit the menu without creating and saving a program for cutting the material. Return to the previous menu. -### 1.3.4 Y CUT +### 1.3.4 Y Cut ![1.3.4.png](/aitalmac-ui/1.3.4.png) A button to open the menu to create a program for automatic cutting of the material. The operator has the option to use the built-in compiler to create simple programs. For linear cuts along the Y-axis. To cut along the Y axis, the machine head will be rotated 90° along the C axis. The icon shows the program execution diagram, from right to left and up. This function is used with a cutting disc. -#### 1.3.4.1 Y-CUT LENGTH +#### 1.3.4.1 Y-Cut Length In the line, you must specify the length of the cut to be performed. The starting point of the cut will occur from the actual position of the cutting tool of the machine above the material. -#### 1.3.4.2 Y-CUT WIDTH +#### 1.3.4.2 Y-Cut Width The line must specify the width of the required cut-out part. After executing the length-cutting command, the machine will rise to a safe height and move to the starting point along the X-axis and offset along the Y-axis with the distance indicated in the row. -#### 1.3.4.3 Y-CUT COUNT +#### 1.3.4.3 Y-Cut Count The number of parts that need to be made must be specified in the line. This will be the number of repetitions of the first two commands to execute the program. -#### 1.3.4.4 GENERATE +#### 1.3.4.4 Generate A button for creating a control program to perform tasks based on previously entered cutting parameters. After clicking, the operator will be able to see the program G-code and visualization on the screen in the upper right corner. -#### 1.3.4.5 EXIT +#### 1.3.4.5 Exit Exit the menu without creating and saving a program for cutting the material. Return to the previous menu. -### 1.3.5 SLOPE +### 1.3.5 Slope ![1.3.5.png](/aitalmac-ui/1.3.5.png) The button to open the menu for creating a slope on the surface of the material using the milling function. The starting point for creating the program will be the actual position of the machine above the material. Along the B axis, the machine should be moved by 90° and the milling tool is positioned perpendicular to the material above the starting point of the milling. -#### 1.3.5.1 POINT 1 DEPTH +#### 1.3.5.1 Point 1 Depth Specify the initial milling depth. Starting from this point, the machine will gradually advance with a uniform deepening to the specified value at Point 2. -#### 1.3.5.2 POINT 2 DEPTH +#### 1.3.5.2 Point 2 Depth Specify the final milling depth. When this depth is reached, the machine will move on to the next command, if possible, or stop and move to a safe position. -#### 1.3.5.3 LENGTH +#### 1.3.5.3 Length Specify the length for the slope milling. At this length, the machine will start working evenly from the initial depth at Point 1 and perform a deepening to the specified parameter of Point 2. -#### 1.3.5.4 WIDTH +#### 1.3.5.4 Width Specify the width of the required slope milling surface. The width must not be less than the diameter of the installed milling tool, otherwise the work may not be done correctly. -#### 1.3.5.5 GENERATE +#### 1.3.5.5 Generate A button for creating a control program to perform tasks based on previously entered cutting parameters. After clicking, the operator will be able to see the program G-code and visualization on the screen in the upper right corner. -#### 1.3.5.6 EXIT +#### 1.3.5.6 Exit Exit the menu without creating and saving a program for cutting the material. Return to the previous menu. -### 1.3.6 MILLING +### 1.3.6 Milling ![1.3.6.png](/aitalmac-ui/1.3.6.png) A button to open the milling menu of the material without a slope, in a strictly horizontal position. It is used to reduce the thickness of the material, on a certain area or on the entire material. The starting point for creating the program will be the actual position of the machine above the material. In the C-axis, the machine must be moved 90° and the milling tool positioned perpendicular to the material above the milling start point. -#### 1.3.6.1 EACH STEP +#### 1.3.6.1 Each Step The amount of deepening of the milling tool into the material in one step. Depending on the final depth, the processing will be divided into layers. -#### 1.3.6.2 TOTAL DEPTH +#### 1.3.6.2 Total Depth The value of the milling depth that the machine must reach by the end of the work. Based on the size of the deepening step, the required number of passes will be made to achieve full depth. -#### 1.3.6.3 MILLING DIRECTION +#### 1.3.6.3 Milling Direction Selection of the milling processing method selection of the required direction of movement and displacement. (0) - milling in the horizontal direction along the X-axis, making parallel passes with the specified offset. (1) - milling in the vertical direction along the Y-axis, making parallel passes with the specified offset. (2) - combined milling in the horizontal and vertical directions along the X and Y axes, performing parallel passes with the specified offset. -#### 1.3.6.4 AREA TO COVER IN X AXIS +#### 1.3.6.4 Area To Cover In X Axis Specify the distance to be milled along the X-axis. The distance will be calculated relative to the center of the tool, not its diameter. These adjustments must be taken into account if it is necessary to perform milling in a limited space of the material. -#### 1.3.6.5 AREA TO COVER IN Y AXIS +#### 1.3.6.5 Area To Cover In Y Axis Specify the distance to be milled along the Y-axis. The distance will be calculated relative to the center of the tool, not its diameter. These adjustments must be taken into account if it is necessary to perform milling in a limited space of the material. -#### 1.3.6.6 WIDTH OF STEPS +#### 1.3.6.6 Width Of Steps Specify the distance for the milling step. This is the offset for the next step, depending on the chosen milling method, it will be performed on the X or Y axis. The distance will be calculated relative to the center of the tool, not its diameter. These adjustments must be taken into account if it is necessary to perform milling operations in a limited material space. -#### 1.3.6.7 GENERATE +#### 1.3.6.7 Generate A button for creating a control program to perform tasks based on previously entered milling parameters. After clicking, the operator will be able to see the program code and visualization on the screen in the upper right corner. -#### 1.3.6.8 EXIT +#### 1.3.6.8 Exit Exit the menu without creating and saving a program for cutting the material. Return to the previous menu. -### 1.3.7 MILLING TABLE +### 1.3.7 Milling Table ![1.3.7.png](/aitalmac-ui/1.3.7.png) A button to open a special menu for milling the workbench in a strictly horizontal position to obtain the ideal level. It is used to reduce the thickness of the material, on a certain area or on the entire material. The starting point for creating the program will be the actual position of the machine above the material. In the C-axis, the machine must be moved 90° and the milling tool positioned perpendicular to the material above the milling start point. -#### 1.3.7.1 EACH STEP +#### 1.3.7.1 Each Step The amount of deepening of the milling tool into the material in one step. Depending on the final depth, the processing will be divided into layers. -#### 1.3.7.2 TOTAL DEPTH +#### 1.3.7.2 Total Depth The value of the milling depth that the machine must reach by the end of the work. Based on the size of the deepening step, the required number of passes will be made to achieve full depth. -#### 1.3.7.3 MILLING DIRECTION +#### 1.3.7.3 Milling Direction Selection of the milling processing method selection of the required direction of movement and displacement. (0) - milling in the horizontal direction along the X-axis, making parallel passes with the specified offset. (1) - milling in the vertical direction along the Y-axis, making parallel passes with the specified offset. (2) - combined milling in the horizontal and vertical directions along the X and Y axes, performing parallel passes with the specified offset. -#### 1.3.7.4 AREA TO COVER IN X AXIS +#### 1.3.7.4 Area To Cover In X Axis Specify the distance to be milled along the X-axis. The distance will be calculated relative to the center of the tool, not its diameter. These adjustments must be taken into account if it is necessary to perform milling in a limited space of the material. -#### 1.3.7.5 AREA TO COVER IN Y AXIS +#### 1.3.7.5 Area To Cover In Y Axis Specify the distance to be milled along the Y-axis. The distance will be calculated relative to the center of the tool, not its diameter. These adjustments must be taken into account if it is necessary to perform milling in a limited space of the material. -#### 1.3.7.6 WIDTH OF STEPS +#### 1.3.7.6 Width Of Steps Specify the distance for the milling step. This is the offset for the next step, depending on the chosen milling method, it will be performed on the X or Y axis. The distance will be calculated relative to the center of the tool, not its diameter. These adjustments must be taken into account if it is necessary to perform milling operations in a limited material space. -#### 1.3.7.7 START X +#### 1.3.7.7 Start X A place to record the required X-axis position in the program parameters to start milling work. It is determined by the operator independently, determines the coordinates in advance in the upper-left menu 1.10. -#### 1.3.7.8 START Y +#### 1.3.7.8 Start Y A place to record the required Y-axis position in the program parameters to start milling work. It is determined by the operator independently, determines the coordinates in advance in the upper-left menu 1.10. -#### 1.3.7.9 PROBE MILLING TOOL +#### 1.3.7.9 Probe Milling Tool Activation of the function of checking the length of the installed milling cutter. After checking, the actual length of the milling cutter will be recorded in the tool parameters and the machine will execute commands with the necessary corrections. The depth of immersion in the worktable, the beginning of milling according to the thickness of the material. This will help to avoid collisions and incorrect milling of the material, as well as collisions with the processed material. -#### 1.3.7.10 CURRENT POSITION +#### 1.3.7.10 Current Position A button for recording X- and Y-axis positions in the program parameters to start milling work. The current position of the machine above the material will be recorded in the program parameters, all previous X and Y coordinates will be overwritten. If the processing coordinates are selected by the operator in advance, then you do not need to use this button. -#### 1.3.7.11 GENERATE +#### 1.3.7.11 Generate A button for creating a control program to perform tasks based on previously entered milling parameters. After clicking, the operator will be able to see the program code and visualization on the screen in the upper right corner. -#### 1.3.7.12 EXIT +#### 1.3.7.12 Exit Exit the menu without creating and saving a program for cutting the material. Return to the previous menu. @@ -989,23 +989,23 @@ Exit the menu without creating and saving a program for cutting the material. Re ![1.4.png](/aitalmac-ui/1.4.png) A mode that allows the operator to enter and execute G-code blocks on the control panel. In manual data entry mode, the code is entered one block at a time, and each block is removed from the machine immediately after execution. -### 1.4.1 LIST +### 1.4.1 List Window to view the last command and previously used ones -### 1.4.2 INFO +### 1.4.2 Info Possibly used and examples of G codes -### 1.4.3 CLEAN +### 1.4.3 Clean Cleaning info window -### 1.4.4 G CODE +### 1.4.4 G Code Line for entering g command code -### 1.4.5 RUN +### 1.4.5 Run Run the entered G code command @@ -1014,734 +1014,734 @@ Run the entered G code command ![1.5.png](/aitalmac-ui/1.5.png) A tab that displays the input control signals from the machine control units. Responsible for safety, the position of the axes of the machine in relation to the limits, buttons and control joysticks, operating and deactivated modules for machine operation. The absence of a signal may be an indicator of an equipment malfunction, and is also necessary for checking and configuring -### 1.5.1 INPUT (1-32) +### 1.5.1 Input (1-32) ![1.5.1_a.png](/aitalmac-ui/1.5.1_a.png) -#### 1.5.1.1 01 [ECAT.11.01] X LIMIT/HOME SENSOR +#### 1.5.1.1 01 [ECAT.11.01] X Limit/Home Sensor Input signal from the sensor along the X axis. -#### 1.5.1.2 02 [ECAT.11.02] Y1 LIMIT/HOME SENSOR +#### 1.5.1.2 02 [ECAT.11.02] Y1 Limit/Home Sensor Input signal from the sensor along the Y1 axis. -#### 1.5.1.3 03 [ECAT.11.03] Y2 LIMIT/HOME SENSOR +#### 1.5.1.3 03 [ECAT.11.03] Y2 Limit/Home Sensor Input signal from the sensor along the Y2 axis. -#### 1.5.1.4 04 [ECAT.11.04] Z LIMIT/HOME SENSOR +#### 1.5.1.4 04 [ECAT.11.04] Z Limit/Home Sensor Input signal from the sensor along the Z axis. -#### 1.5.1.5 05 [ECAT.11.05] C HOME SENSOR +#### 1.5.1.5 05 [ECAT.11.05] C Home Sensor Input signal from the sensor along the C axis. -#### 1.5.1.6 06 [ECAT.11.06] B HOME SENSOR +#### 1.5.1.6 06 [ECAT.11.06] B Home Sensor Input signal from the sensor along the B axis. -#### 1.5.1.7 07 [ECAT.11.07] V HOME SENSOR +#### 1.5.1.7 07 [ECAT.11.07] V Home Sensor Input signal from the sensor along the V axis. -#### 1.5.1.8 08 [ECAT.11.08] SCANNER UP +#### 1.5.1.8 08 [ECAT.11.08] Scanner Up Input signal from the sensor on the pneumatic cylinder to determine the position at the top. -#### 1.5.1.9 09 [ECAT.11.09] STONE PROBE SAFETY +#### 1.5.1.9 09 [ECAT.11.09] Stone Probe Safety Input signal from the sensor on the pneumatic cylinder to determine the position at the top. -#### 1.5.1.10 10 [ECAT.11.10] STONE PROBE +#### 1.5.1.10 10 [ECAT.11.10] Stone Probe Input signal from the sensor on the pneumatic cylinder to determine the position at the bottom. -#### 1.5.1.11 11 [ECAT.11.11] VACUUM GROUP 1 IS DOWN +#### 1.5.1.11 11 [ECAT.11.11] Vacuum Group 1 is Down Input signal from the sensor on the pneumatic cylinder to determine the position at the bottom. -#### 1.5.1.12 12 [ECAT.11.12] VACUUM GROUP 2 IS DOWN +#### 1.5.1.12 12 [ECAT.11.12] Vacuum Group 2 is Down Input signal from the sensor on the pneumatic cylinder to determine the position at the bottom. -#### 1.5.1.13 13 [ECAT.11.13] VACUUM GROUP 1 TILTED +#### 1.5.1.13 13 [ECAT.11.13] Vacuum Group 1 Tilted Input signal from the sensor on the pneumatic cylinder to determine the position at the bottom. -#### 1.5.1.14 14 [ECAT.11.14] VACUUM GROUP 2 TILTED +#### 1.5.1.14 14 [ECAT.11.14] Vacuum Group 2 Tilted Input signal from the sensor on the pneumatic cylinder to determine the position at the bottom. -#### 1.5.1.15 15 [ECAT.11.15] BLADE PROBE +#### 1.5.1.15 15 [ECAT.11.15] Blade Probe The output signal from the probe is for measuring the diameter of the blade. The first position of touching the probe with the blade. -#### 1.5.1.16 16 [ECAT.11.16] BLADE PROBE SAFETY +#### 1.5.1.16 16 [ECAT.11.16] Blade Probe Safety The output signal from the sensor is designed to measure the diameter of the blade. The second safety position of the sensor is with the blade. -#### 1.5.1.17 17 [ECAT.12.01] VACUUM 1 IN PRESSURE +#### 1.5.1.17 17 [ECAT.12.01] Vacuum 1 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.18 18 [ECAT.12.02] VACUUM 2 IN PRESSURE +#### 1.5.1.18 18 [ECAT.12.02] Vacuum 2 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.19 19 [ECAT.12.03] VACUUM 3 IN PRESSURE +#### 1.5.1.19 19 [ECAT.12.03] Vacuum 3 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.20 20 [ECAT.12.04] VACUUM 4 IN PRESSURE +#### 1.5.1.20 20 [ECAT.12.04] Vacuum 4 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.21 21 [ECAT.12.05] VACUUM 5 IN PRESSURE +#### 1.5.1.21 21 [ECAT.12.05] Vacuum 5 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.22 22 [ECAT.12.06] VACUUM 6 IN PRESSURE +#### 1.5.1.22 22 [ECAT.12.06] Vacuum 6 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.23 23 [ECAT.12.07] VACUUM 7 IN PRESSURE +#### 1.5.1.23 23 [ECAT.12.07] Vacuum 7 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.24 24 [ECAT.12.08] VACUUM 8 IN PRESSURE +#### 1.5.1.24 24 [ECAT.12.08] Vacuum 8 in Pressure Input signal from the sensor on the vacuum generator, switching on and off. -#### 1.5.1.25 25 [ECAT.12.09] WATERJET UP +#### 1.5.1.25 25 [ECAT.12.09] Waterjet Up Input signal from the sensor on the air cylinder to determine the position at the top. -#### 1.5.1.26 26 [ECAT.12.10] WATERJET DOWN +#### 1.5.1.26 26 [ECAT.12.10] Waterjet Down Input signal from the sensor on the air cylinder to determine the position at the bottom. -#### 1.5.1.27 27 [ECAT.12.11] TABLE OPEN +#### 1.5.1.27 27 [ECAT.12.11] Table Open Input signal from the sensor on the hydraulic cylinder to determine the position of the open table. -#### 1.5.1.28 28 [ECAT.12.12] TABLE CLOSE +#### 1.5.1.28 28 [ECAT.12.12] Table Close Input signal from the sensor on the hydraulic cylinder to determine the down position. -#### 1.5.1.29 29 [ECAT.12.13] NONE +#### 1.5.1.29 29 [ECAT.12.13] None The input signal on the control card is not assigned -#### 1.5.1.30 30 [ECAT.12.14] NONE +#### 1.5.1.30 30 [ECAT.12.14] None The input signal on the control card is not assigned -#### 1.5.1.31 31 [ECAT.12.15] NONE +#### 1.5.1.31 31 [ECAT.12.15] None The input signal on the control card is not assigned -#### 1.5.1.32 32 [ECAT.12.16] NONE +#### 1.5.1.32 32 [ECAT.12.16] None The input signal on the control card is not assigned -### 1.5.1 INPUT (33-64) +### 1.5.1 Input (33-64) ![1.5.1_b.png](/aitalmac-ui/1.5.1_b.png) -#### 1.5.1.33 33 [ECAT.17.01] BUTTON AUTOMATIC +#### 1.5.1.33 33 [ECAT.17.01] Button Automatic Feedback from the start automatic operation button. -#### 1.5.1.34 34 [ECAT.17.02] BUTTON PAUSE +#### 1.5.1.34 34 [ECAT.17.02] Button Pause Feedback from the pause button of automatic operation. -#### 1.5.1.35 35 [ECAT.17.03] BUTTON STOP +#### 1.5.1.35 35 [ECAT.17.03] Button Stop Feedback from the stop button of automatic operation. -#### 1.5.1.36 36 [ECAT.17.04] SWITCH TCP +#### 1.5.1.36 36 [ECAT.17.04] Switch TCP Feedback signal for switching on the switch to activate axis interpolation -#### 1.5.1.37 37 [ECAT.17.05] SWITCH 45 DEG +#### 1.5.1.37 37 [ECAT.17.05] Switch 45 Deg Feedback is a signal to turn on the switch to activate the rotation of the head by 45° along the B axis -#### 1.5.1.38 38 [ECAT.17.06] SWITCH 90 DEG +#### 1.5.1.38 38 [ECAT.17.06] Switch 90 Deg Feedback is a signal to turn on the switch to activate the rotation of the head by 90° along the B axis -#### 1.5.1.39 39 [ECAT.17.07] JOYSTICK X+ +#### 1.5.1.39 39 [ECAT.17.07] Joystick X+ Feedback is a signal to turn on the movement of the machine in the positive direction along the X-axis using the joystick on the control panel. -#### 1.5.1.40 40 [ECAT.17.08] JOYSTICK X- +#### 1.5.1.40 40 [ECAT.17.08] Joystick X- Feedback is a signal to turn on the movement of the machine in the negative direction along the X-axis using the joystick on the control panel. -#### 1.5.1.41 41 [ECAT.17.09] JOYSTICK Y+ +#### 1.5.1.41 41 [ECAT.17.09] Joystick Y+ Feedback is a signal to turn on the movement of the machine in the positive direction along the Y-axis using the joystick on the control panel. -#### 1.5.1.42 42 [ECAT.17.10] JOYSTICK Y- +#### 1.5.1.42 42 [ECAT.17.10] Joystick Y- Feedback is a signal to turn on the movement of the machine in the negative direction along the Y-axis using the joystick on the control panel. -#### 1.5.1.43 43 [ECAT.17.11] JOYSTICK Z+ +#### 1.5.1.43 43 [ECAT.17.11] Joystick Z+ Feedback is a signal to turn on the movement of the machine in the positive direction along the Z-axis using the joystick on the control panel. -#### 1.5.1.44 44 [ECAT.17.12] JOYSTICK Z- +#### 1.5.1.44 44 [ECAT.17.12] Joystick Z- Feedback is a signal to turn on the movement of the machine in the negative direction along the Z-axis using the joystick on the control panel. -#### 1.5.1.45 45 [ECAT.17.13] JOYSTICK C+ +#### 1.5.1.45 45 [ECAT.17.13] Joystick C+ Feedback is a signal to turn on the movement of the machine in the positive direction along the C-axis using the joystick on the control panel. -#### 1.5.1.46 46 [ECAT.17.14] JOYSTICK C- +#### 1.5.1.46 46 [ECAT.17.14] Joystick C- Feedback is a signal to turn on the movement of the machine in the negative direction along the C-axis using the joystick on the control panel. -#### 1.5.1.47 47 [ECAT.17.15] JOYSTICK B+ +#### 1.5.1.47 47 [ECAT.17.15] Joystick B+ Feedback is a signal to turn on the movement of the machine in the positive direction along the B-axis using the joystick on the control panel. -#### 1.5.1.48 48 [ECAT.17.16] JOYSTICK B- +#### 1.5.1.48 48 [ECAT.17.16] Joystick B- Feedback is a signal to turn on the movement of the machine in the negative direction along the B-axis using the joystick on the control panel. -#### 1.5.1.49 49 [ECAT.18.01] SPEED ENCODER A +#### 1.5.1.49 49 [ECAT.18.01] Speed Encoder A -#### 1.5.1.50 50 [ECAT.18.02] SPEED ENCODER B +#### 1.5.1.50 50 [ECAT.18.02] Speed Encoder B -#### 1.5.1.51 51 [ECAT.18.03] EMERGENCY +#### 1.5.1.51 51 [ECAT.18.03] Emergency Feedback from the emergency stop button. The signal indicates that the button is on. -#### 1.5.1.52 52 [ECAT.18.04] NONE +#### 1.5.1.52 52 [ECAT.18.04] None The input signal on the control card is not assigned -#### 1.5.1.53 53 [ECAT.18.05] NONE +#### 1.5.1.53 53 [ECAT.18.05] None The input signal on the control card is not assigned -#### 1.5.1.54 54 [ECAT.18.06] NONE +#### 1.5.1.54 54 [ECAT.18.06] None The input signal on the control card is not assigned -#### 1.5.1.55 55 [ECAT.18.07] NONE +#### 1.5.1.55 55 [ECAT.18.07] None The input signal on the control card is not assigned -#### 1.5.1.56 56 [ECAT.18.08] NONE +#### 1.5.1.56 56 [ECAT.18.08] None The input signal on the control card is not assigned -#### 1.5.1.57 57 [ECAT.18.09] NONE +#### 1.5.1.57 57 [ECAT.18.09] None The input signal on the control card is not assigned -#### 1.5.1.58 58 [ECAT.18.10] NONE +#### 1.5.1.58 58 [ECAT.18.10] None The input signal on the control card is not assigned -#### 1.5.1.59 59 [ECAT.18.11] NONE +#### 1.5.1.59 59 [ECAT.18.11] None The input signal on the control card is not assigned -#### 1.5.1.60 60 [ECAT.18.12] NONE +#### 1.5.1.60 60 [ECAT.18.12] None The input signal on the control card is not assigned -#### 1.5.1.61 61 [ECAT.18.13] NONE +#### 1.5.1.61 61 [ECAT.18.13] None The input signal on the control card is not assigned -#### 1.5.1.62 62 [ECAT.18.14] NONE +#### 1.5.1.62 62 [ECAT.18.14] None The input signal on the control card is not assigned -#### 1.5.1.63 63 [ECAT.18.15] NONE +#### 1.5.1.63 63 [ECAT.18.15] None The input signal on the control card is not assigned -#### 1.5.1.64 64 [ECAT.18.16] NONE +#### 1.5.1.64 64 [ECAT.18.16] None The input signal on the control card is not assigned -### 1.5.1 INPUT (65-96) +### 1.5.1 Input (65-96) ![1.5.1_c.png](/aitalmac-ui/1.5.1_c.png) -#### 1.5.1.65 65 [ECAT.10.1] POWER OFF ALARM +#### 1.5.1.65 65 [ECAT.10.1] Power Off Alarm The input signal indicating a power failure due to an error is incompatible with the machine's ability to continue operation. -#### 1.5.1.66 66 [ECAT.10.2] VACUUM PUMP THERMIC ALARM +#### 1.5.1.66 66 [ECAT.10.2] Vacuum Pump Thermic Alarm The initial input for the thermal protection mechanism of the vacuum motor. -#### 1.5.1.67 67 [ECAT.10.3] HYDRAULIC PUMP THERMIC ALARM +#### 1.5.1.67 67 [ECAT.10.3] Hydraulic Pump Thermic Alarm The initial input for the thermal protection mechanism of the hydraulic motor. -#### 1.5.1.68 68 [ECAT.10.4] AIR ALARM +#### 1.5.1.68 68 [ECAT.10.4] Air Alarm The input signal is obtained from the readings of the air pressure sensor located at the entrance of the machine. If the air pressure falls below a certain threshold, a trigger event is activated. -#### 1.5.1.69 69 [ECAT.10.5] WATER ALARM +#### 1.5.1.69 69 [ECAT.10.5] Water Alarm The input signal is obtained from the readings of the water pressure sensor located at the entrance of the machine. If the water pressure falls below a certain threshold, a trigger event is activated. -#### 1.5.1.70 70 [ECAT.10.6] GARNET LEVEL ALARM +#### 1.5.1.70 70 [ECAT.10.6] Garnet Level Alarm The output signal is generated based on the readings of a capacitive sensor located in the garnet abrasive tank. If the abrasive level falls below a certain threshold value, a trigger event is activated. -#### 1.5.1.71 71 [ECAT.10.7] GARNET PRESSURE ALARM +#### 1.5.1.71 71 [ECAT.10.7] Garnet Pressure Alarm The output signal is generated based on the readings of the pressure sensor in the garnet abrasive tank. If the pressure in the tank drops below a certain level, automatic abrasive supply becomes impossible and an alert is triggered. -#### 1.5.1.72 72 [ECAT.10.8] SAFETY BAR +#### 1.5.1.72 72 [ECAT.10.8] Safety Bar The output signal is generated based on the readings from the safety sensor during machine operation. If these readings indicate a potential emergency, the signal stops the machine operation to prevent any further accidents in the machine area. -#### 1.5.1.73 73 [ECAT.10.9] NONE +#### 1.5.1.73 73 [ECAT.10.9] None The input signal on the control card is not assigned -#### 1.5.1.74 74 [ECAT.10.10] SPINDLE HOT ALARM +#### 1.5.1.74 74 [ECAT.10.10] Spindle Hot Alarm The input signal is generated based on the readings of the spindle's overheating sensor during the thermal test. If a signal is detected, the spindle will stop to prevent serious damage. -#### 1.5.1.75 75 [ECAT.10.11] SPINDLE MOTOR CHILLER ALARM +#### 1.5.1.75 75 [ECAT.10.11] Spindle Motor Chiller Alarm The output signal is generated based on readings from the Chiller control panel. If a signal is received, the power supply is stopped to prevent serious damage. It is necessary to fix the problem on the Chiller. -#### 1.5.1.76 76 [ECAT.10.12] WATERJET HOT ALARM +#### 1.5.1.76 76 [ECAT.10.12] Waterjet Hot Alarm The input signal is generated based on the readings (thermal test) of the motor overheating sensor. If a signal is received, the motor power supply stops to prevent serious damage. -#### 1.5.1.77 77 [ECAT.10.13] WATERJET CHILLER ALARM +#### 1.5.1.77 77 [ECAT.10.13] Waterjet Chiller Alarm The output signal is generated based on readings from the Chiller control panel. If a signal is received, the power supply is stopped to prevent serious damage. It is necessary to fix the problem on the Chiller. -#### 1.5.1.78 78 [ECAT.10.14] NONE +#### 1.5.1.78 78 [ECAT.10.14] None The input signal on the control card is not assigned -#### 1.5.1.79 79 [ECAT.10.15] NONE +#### 1.5.1.79 79 [ECAT.10.15] None The input signal on the control card is not assigned -#### 1.5.1.80 80 [ECAT.10.16] NONE +#### 1.5.1.80 80 [ECAT.10.16] None The input signal on the control card is not assigned -#### 1.5.1.81 81 [ECAT.16.1] TILTER VACUUM 1 IN PRESSURE +#### 1.5.1.81 81 [ECAT.16.1] Tilter Vacuum 1 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.82 82 [ECAT.16.2] TILTER VACUUM 2 IN PRESSURE +#### 1.5.1.82 82 [ECAT.16.2] Tilter Vacuum 2 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.83 83 [ECAT.16.3] TILTER VACUUM 3 IN PRESSURE +#### 1.5.1.83 83 [ECAT.16.3] Tilter Vacuum 3 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flippinf the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.84 84 [ECAT.16.4] TILTER VACUUM 4 IN PRESSURE +#### 1.5.1.84 84 [ECAT.16.4] Tilter Vacuum 4 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.85 85 [ECAT.16.5] TILTER VACUUM 5 IN PRESSURE +#### 1.5.1.85 85 [ECAT.16.5] Tilter Vacuum 5 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.86 86 [ECAT.16.6] TILTER VACUUM 6 IN PRESSURE +#### 1.5.1.86 86 [ECAT.16.6] Tilter Vacuum 6 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.87 87 [ECAT.16.7] TILTER VACUUM 7 IN PRESSURE +#### 1.5.1.87 87 [ECAT.16.7] Tilter Vacuum 7 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.88 88 [ECAT.16.8] TILTER VACUUM 8 IN PRESSURE +#### 1.5.1.88 88 [ECAT.16.8] Tilter Vacuum 8 in Pressure The input signal from the vacuum monitoring sensor on the suction cups indicates whether there is a vacuum present or not. If the vacuum is created on a suction cup, it is possible to lift and flipping the material on the workbench. If not, a signal will appear to check the suction cup with the number where there is no vacuum. -#### 1.5.1.89 89 [ECAT.16.9] TILTER AT 0A° +#### 1.5.1.89 89 [ECAT.16.9] Tilter At 0a° The input signal comes from the position sensor of the additional vacuum suction cups. The suction cups are lifted and rotated to flip the material. -#### 1.5.1.90 90 [ECAT.16.10] TILTER AT 180A° +#### 1.5.1.90 90 [ECAT.16.10] Tilter At 180a° The input signal from the position sensor of the additional vacuum suction cups. The suction cups are lowered and the machine can perform work on flipping the material on the workbench. -#### 1.5.1.91 91 [ECAT.16.11] FLIPPER SAFETY +#### 1.5.1.91 91 [ECAT.16.11] Flipper Safety The input signal is from the position sensor of the plate flip system with vacuum suction cups. The suction cups are lowered to a safe position and the machine can perform cutting and milling operations. -#### 1.5.1.92 92 [ECAT.16.12] NONE +#### 1.5.1.92 92 [ECAT.16.12] None The input signal on the control card is not assigned -#### 1.5.1.93 93 [ECAT.16.13] NONE +#### 1.5.1.93 93 [ECAT.16.13] None The input signal on the control card is not assigned -#### 1.5.1.94 94 [ECAT.16.14] NONE +#### 1.5.1.94 94 [ECAT.16.14] None The input signal on the control card is not assigned -#### 1.5.1.95 95 [ECAT.16.15] NONE +#### 1.5.1.95 95 [ECAT.16.15] None The input signal on the control card is not assigned -#### 1.5.1.96 96 [ECAT.16.16] NONE +#### 1.5.1.96 96 [ECAT.16.16] None The input signal on the control card is not assigned -## 1.5.1 INPUT (97-108) +## 1.5.1 Input (97-108) ![1.5.1_d.png](/aitalmac-ui/1.5.1_d.png) -#### 1.5.1.97 REMOTE SPD+ +#### 1.5.1.97 Remote Spd+ The input signal is a change in the speed of the spindle as a percentage of its initial speed. -#### 1.5.1.98 REMOTE BLADE ON +#### 1.5.1.98 Remote Blade On Input signal for turning on the spindle from the remote control -#### 1.5.1.99 REMOTE SPD- +#### 1.5.1.99 Remote Spd- The input signal is used to reduce the speed of the spindle as a percentage of its initial speed. -#### 1.5.1.100 REMOTE CONFIRM +#### 1.5.1.100 Remote Confirm The input signal for connecting the remote control -#### 1.5.1.101 REMOTE Y+ +#### 1.5.1.101 Remote Y+ An input signal to enable the movement of the machine in a positive direction along the Y-axis using the remote control. -#### 1.5.1.102 REMOTE Y- +#### 1.5.1.102 Remote Y- An input signal to turn on the movement of the machine in the negative direction along the Y-axis using the remote control. -#### 1.5.1.103 REMOTE C+ +#### 1.5.1.103 Remote C+ An input signal to enable the movement of the machine in a positive direction along the C-axis using the remote control. -#### 1.5.1.104 REMOTE C- +#### 1.5.1.104 Remote C- An input signal to turn on the movement of the machine in the negative direction along the C-axis using the remote control. -#### 1.5.1.105 REMOTE X- +#### 1.5.1.105 Remote X- An input signal to turn on the movement of the machine in the negative direction along the X-axis using the remote control. -#### 1.5.1.106 REMOTE Z- +#### 1.5.1.106 Remote Z- An input signal to turn on the movement of the machine in the negative direction along the Z-axis using the remote control. -#### 1.5.1.107 REMOTE Z+ +#### 1.5.1.107 Remote Z+ An input signal to enable the movement of the machine in a positive direction along the Z-axis using the remote control. -#### 1.5.1.108 REMOTE X+ +#### 1.5.1.108 Remote X+ An input signal to enable the movement of the machine in a positive direction along the X-axis using the remote control. -### 1.5.2 OUTPUT (1-32) +### 1.5.2 Output (1-32) ![1.5.2_a.png](/aitalmac-ui/1.5.2_a.png) A tab with the output signals from the main modules and components of the machine. The operator can use this tab to check the operation of selected commands, see how the machine is performing, and, if necessary, make adjustments.Care must be taken when using the output signals, because the commands are forced and do not match the safe positions of the machine. -#### 1.5.2.1 01 [ECAT.13.01] ENABLE MACHINE +#### 1.5.2.1 01 [ECAT.13.01] Enable Machine Activates the machine. This signal also triggers when the machine is turned on from the operator menu. -#### 1.5.2.2 02 [ECAT.13.02] RESET CAMERA +#### 1.5.2.2 02 [ECAT.13.02] Reset Camera Resets (reboots) the camera used for taking images of material on the workbench. This is useful when the camera loses connection. -#### 1.5.2.3 03 [ECAT.13.03] WATERJET ENABLE +#### 1.5.2.3 03 [ECAT.13.03] Waterjet Enable Activates the water jet. This signal is also given when the machine is turned on from the operator's menu. -#### 1.5.2.4 04 [ECAT.13.04] VACUUM PUMP +#### 1.5.2.4 04 [ECAT.13.04] Vacuum Pump Activates the vacuum pump, creating a vacuum in the system. This signal is necessary for testing all vacuum suction cups. Each suction cup can be tested individually by activating its respective output signal. -#### 1.5.2.5 05 [ECAT.13.05] HYDRAULIC PUMP +#### 1.5.2.5 05 [ECAT.13.05] Hydraulic Pump Activates the hydraulic station motor. This begins building oil pressure for lifting the workbench. Without this signal, the hydraulic distributor will keep the workbench in its initial position. -#### 1.5.2.6 06 [ECAT.13.06] GREASE PUMP +#### 1.5.2.6 06 [ECAT.13.06] Grease Pump Activates the automatic lubrication pump. The pump normally operates at set intervals and durations, but manual activation can verify lubrication flow after refilling the grease tank or during maintenance of lubrication lines. -#### 1.5.2.7 07 [ECAT.13.07] CHILLER SWITCH +#### 1.5.2.7 07 [ECAT.13.07] Chiller Switch Activating chiller shutdown -#### 1.5.2.8 08 [ECAT.13.08] TABLE SLOW SWITCH VALVE +#### 1.5.2.8 08 [ECAT.13.08] Table Slow Switch Valve ??? -#### 1.5.2.9 09 [ECAT.13.09] SLAB WASH +#### 1.5.2.9 09 [ECAT.13.09] Slab Wash Activates the material cleaning system. This opens the water supply valve for cleaning nozzles. -#### 1.5.2.10 10 [ECAT.13.10] WATERJET GUN +#### 1.5.2.10 10 [ECAT.13.10] Waterjet Gun ??? -#### 1.5.2.11 11 [ECAT.13.11] INTERNAL WATER +#### 1.5.2.11 11 [ECAT.13.11] Internal Water Enables water flow through the spindle center for milling operations. Activating this signal opens the respective water and air supply valves. -#### 1.5.2.12 12 [ECAT.13.12] EXTERNAL WATER +#### 1.5.2.12 12 [ECAT.13.12] External Water Enables the external cooling system for tools, such as blades. This signal opens the valve to supply water through nozzles directed at the blade. -#### 1.5.2.13 13 [ECAT.13.13] TABLE UP +#### 1.5.2.13 13 [ECAT.13.13] Table Up Activates the solenoids of the hydraulic distributor to forcibly lift the workbench. This requires the hydraulic station to be active. Without it, the distributor will only switch the oil flow to the lift cylinder. The command bypasses safe position checks, requiring operator supervision. -#### 1.5.2.14 14 [ECAT.13.14] TABLE DOWN +#### 1.5.2.14 14 [ECAT.13.14] Table Down Activates the solenoids of the hydraulic distributor to forcibly lower the workbench. This requires the hydraulic station to be active. Without it, the distributor will only switch the oil flow to the cylinder for lowering. The command bypasses safe position checks, requiring operator supervision. -#### 1.5.2.15 15 [ECAT.15.15] SCANER DOWN +#### 1.5.2.15 15 [ECAT.15.15] Scaner Down Lowers the laser scanner module for material thickness measurement along the cutting path. The command ignores Z-axis safe position checks, so operators must ensure the head is positioned to avoid collisions. -#### 1.5.2.16 16 [ECAT.13.16] BLADE LASER +#### 1.5.2.16 16 [ECAT.13.16] Blade Laser Enables the blade laser line for alignment checks. Pressing the button again turns off the laser. -#### 1.5.2.17 17 [ECAT.14.01] VACUUM 1 +#### 1.5.2.17 17 [ECAT.14.01] Vacuum 1 Activates the vacuum for suction cup 1. This signal only works when the vacuum pump is active. -#### 1.5.2.18 18 [ECAT.14.02] VACUUM 2 +#### 1.5.2.18 18 [ECAT.14.02] Vacuum 2 Activates the vacuum for suction cup 2. This signal only works when the vacuum pump is active. -#### 1.5.2.19 19 [ECAT.14.03] VACUUM 3 +#### 1.5.2.19 19 [ECAT.14.03] Vacuum 3 Activates the vacuum for suction cup 3. This signal only works when the vacuum pump is active. -#### 1.5.2.20 20 [ECAT.14.04] VACUUM 4 +#### 1.5.2.20 20 [ECAT.14.04] Vacuum 4 Activates the vacuum for suction cup 4. This signal only works when the vacuum pump is active. -#### 1.5.2.21 21 [ECAT.14.05] VACUUM 5 +#### 1.5.2.21 21 [ECAT.14.05] Vacuum 5 Activates the vacuum for suction cup 5. This signal only works when the vacuum pump is active. -#### 1.5.2.22 22 [ECAT.14.06] VACUUM 6 +#### 1.5.2.22 22 [ECAT.14.06] Vacuum 6 Activates the vacuum for suction cup 6. This signal only works when the vacuum pump is active. -#### 1.5.2.23 23 [ECAT.14.07] VACUUM 7 +#### 1.5.2.23 23 [ECAT.14.07] Vacuum 7 Activates the vacuum for suction cup 7. This signal only works when the vacuum pump is active. -#### 1.5.2.24 24 [ECAT.14.08] VACUUM 8 +#### 1.5.2.24 24 [ECAT.14.08] Vacuum 8 Activates the vacuum for suction cup 8. This signal only works when the vacuum pump is active. -#### 1.5.2.25 25 [ECAT.14.09] VACUUM GROUP 1 DOWN +#### 1.5.2.25 25 [ECAT.14.09] Vacuum Group 1 Down Activates the signal to lower vacuum modules in Group 1. Operators must ensure sufficient Z-axis clearance before initiating this action to avoid collisions. -#### 1.5.2.26 26 [ECAT.14.10] VACUUM GROUP 2 DOWN +#### 1.5.2.26 26 [ECAT.14.10] Vacuum Group 2 Down Activates the signal to lower vacuum modules in Group 2. Like Group 1, operators must verify adequate Z-axis clearance prior to operation. -#### 1.5.2.27 27 [ECAT.14.11] VACUUM GROUP 1 TILT +#### 1.5.2.27 27 [ECAT.14.11] Vacuum Group 1 Tilt Tilts vacuum modules in Group 1 horizontally. Ensure Z-axis clearance is sufficient to prevent interference during operation. -#### 1.5.2.28 28 [ECAT.14.12] VACUUM GROUP 2 TILT +#### 1.5.2.28 28 [ECAT.14.12] Vacuum Group 2 Tilt Tilts vacuum modules in Group 2 horizontally. Operators should confirm Z-axis clearance before activating this signal. -#### 1.5.2.29 29 [ECAT.14.13] SLAB PROBE CYLINDER +#### 1.5.2.29 29 [ECAT.14.13] Slab Probe Cylinder Lowers the probe for material thickness measurement. Activating the signal opens the air supply valve, and deactivating it retracts the probe. -#### 1.5.2.30 30 [ECAT.14.14] PNEUMATIC SPINDLE SEAL +#### 1.5.2.30 30 [ECAT.14.14] Pneumatic Spindle Seal Enables air supply through the spindle center for sealing. The operator can adjust pressure or check seal integrity. -#### 1.5.2.31 31 [ECAT.14.15] WATERJET GARNET +#### 1.5.2.31 31 [ECAT.14.15] Waterjet Garnet Opens the valve to supply garnet for the waterjet cutting head. Operators should flush the tube after manual operation to prevent blockages. -#### 1.5.2.32 32 [ECAT.14.16] WATERJET DOWN +#### 1.5.2.32 32 [ECAT.14.16] Waterjet Down Lowers the waterjet cutting head into position. Operators must ensure sufficient Z-axis clearance before activation. -### 1.5.2 OUTPUT (33-48) +### 1.5.2 Output (33-48) ![1.5.2_b.png](/aitalmac-ui/1.5.2_b.png) -#### 1.5.2.33 33 [ECAT.19.01] RED LIGHT +#### 1.5.2.33 33 [ECAT.19.01] Red Light Activates the red warning light on the control panel. The red light signals errors or alerts operators that the machine is ready for operation. -#### 1.5.2.34 34 [ECAT.19.02] YELLOW LIGHT +#### 1.5.2.34 34 [ECAT.19.02] Yellow Light Activates the yellow light on the control panel. The yellow light signals that the machine is in pause mode. However, this output forces the yellow light on regardless of the actual machine state and can be used to test the signal lamp. -#### 1.5.2.35 35 [ECAT.19.03] GREEN LIGHT +#### 1.5.2.35 35 [ECAT.19.03] Green Light Activates the green light on the control panel. A green light warns the operator when the machine is working. -#### 1.5.2.36 36 [ECAT.19.04] WHITE LIGHT +#### 1.5.2.36 36 [ECAT.19.04] White Light Activates the white light on the control panel. A white light warns the operator about making machine settings -#### 1.5.2.37 37 [ECAT.19.05] TCP LIGHT +#### 1.5.2.37 37 [ECAT.19.05] TCP Light Activates the green illumination of the switch. The green light indicates that interpolation is enabled. -#### 1.5.2.38 38 [ECAT.19.06] NONE +#### 1.5.2.38 38 [ECAT.19.06] None The output signal on the control board is not set -#### 1.5.2.39 39 [ECAT.19.07] NONE +#### 1.5.2.39 39 [ECAT.19.07] None The output signal on the control board is not set -#### 1.5.2.40 40 [ECAT.19.08] NONE +#### 1.5.2.40 40 [ECAT.19.08] None The output signal on the control board is not set -#### 1.5.2.41 41 [ECAT.19.09] NONE +#### 1.5.2.41 41 [ECAT.19.09] None The output signal on the control board is not set -#### 1.5.2.42 42 [ECAT.19.10] NONE +#### 1.5.2.42 42 [ECAT.19.10] None The output signal on the control board is not set -#### 1.5.2.43 43 [ECAT.19.11] NONE +#### 1.5.2.43 43 [ECAT.19.11] None The output signal on the control board is not set -#### 1.5.2.44 44 [ECAT.19.12] NONE +#### 1.5.2.44 44 [ECAT.19.12] None The output signal on the control board is not set -#### 1.5.2.45 45 [ECAT.19.13] NONE +#### 1.5.2.45 45 [ECAT.19.13] None The output signal on the control board is not set -#### 1.5.2.46 46 [ECAT.19.14] NONE +#### 1.5.2.46 46 [ECAT.19.14] None The output signal on the control board is not set -#### 1.5.2.47 47 [ECAT.19.15] NONE +#### 1.5.2.47 47 [ECAT.19.15] None The output signal on the control board is not set -#### 1.5.2.48 48 [ECAT.19.16] NONE +#### 1.5.2.48 48 [ECAT.19.16] None The output signal on the control board is not set -### 1.5.3 DOUT (1-16) +### 1.5.3 Dout (1-16) ![1.5.3.png](/aitalmac-ui/1.5.3.png) -#### 1.5.3.1 1 [ECAT.15.01] FLIPPER VAC 1 +#### 1.5.3.1 1 [ECAT.15.01] Flipper Vac 1 Activates the vacuum suction cup (1) on the tile flip module. -#### 1.5.3.2 42 [ECAT.15.02] FLIPPER VAC 2 +#### 1.5.3.2 42 [ECAT.15.02] Flipper Vac 2 Activates the vacuum suction cup (2) on the tile flip module. -#### 1.5.3.3 43 [ECAT.15.03] FLIPPER VAC 3 +#### 1.5.3.3 43 [ECAT.15.03] Flipper Vac 3 Activates the vacuum suction cup (3) on the tile flip module. -#### 1.5.3.4 44 [ECAT.15.04] FLIPPER VAC 4 +#### 1.5.3.4 44 [ECAT.15.04] Flipper Vac 4 Activates the vacuum suction cup (4) on the tile flip module. -#### 1.5.3.5 45 [ECAT.15.05] FLIPPER VAC 5 +#### 1.5.3.5 45 [ECAT.15.05] Flipper Vac 5 Activates the vacuum suction cup (5) on the tile flip module. -#### 1.5.3.6 46 [ECAT.15.06] FLIPPER VAC 6 +#### 1.5.3.6 46 [ECAT.15.06] Flipper Vac 6 Activates the vacuum suction cup (6) on the tile flip module. -#### 1.5.3.7 47 [ECAT.15.07] FLIPPER VAC 7 +#### 1.5.3.7 47 [ECAT.15.07] Flipper Vac 7 Activates the vacuum suction cup (7) on the tile flip module. -#### 1.5.3.8 48 [ECAT.15.08] FLIPPER VAC 8 +#### 1.5.3.8 48 [ECAT.15.08] Flipper Vac 8 Activates the vacuum suction cup (8) on the tile flip module. -#### 1.5.3.9 49 [ECAT.15.09] FLIPPER FLIP +#### 1.5.3.9 49 [ECAT.15.09] Flipper Flip Activates a 180° rotation of the module. The command will execute without safety checks, so the operator must carefully monitor the module's position. -#### 1.5.3.10 59 [ECAT.15.10] NONE +#### 1.5.3.10 59 [ECAT.15.10] None The output signal on the control board is not set -#### 1.5.3.11 60 [ECAT.15.11] NONE +#### 1.5.3.11 60 [ECAT.15.11] None The output signal on the control board is not set -#### 1.5.3.12 61 [ECAT.15.12] NONE +#### 1.5.3.12 61 [ECAT.15.12] None The output signal on the control board is not set -#### 1.5.3.13 62 [ECAT.15.13] NONE +#### 1.5.3.13 62 [ECAT.15.13] None The output signal on the control board is not set -#### 1.5.3.14 63 [ECAT.15.14] NONE +#### 1.5.3.14 63 [ECAT.15.14] None The output signal on the control board is not set -#### 1.5.3.15 64 [ECAT.15.15] NONE +#### 1.5.3.15 64 [ECAT.15.15] None The output signal on the control board is not set -#### 1.5.3.16 65 [ECAT.15.16] NONE +#### 1.5.3.16 65 [ECAT.15.16] None The output signal on the control board is not set -### 1.5.4 SERVICE +### 1.5.4 Service ![1.5.4.png](/aitalmac-ui/1.5.4.png) This section displays operational data for the machine and motors, including total running hours (machine hours), to facilitate timely maintenance. -#### 1.5.4.1 MACHINE HOURS +#### 1.5.4.1 Machine Hours Displays the total runtime of the machine from its first activation to the most recent shutdown. -#### 1.5.4.2 SPINDLE HOURS +#### 1.5.4.2 Spindle Hours Shows the cumulative runtime of the spindle from its initial activation to the most recent shutdown. -#### 1.5.4.3 WATERJET HOURS +#### 1.5.4.3 Waterjet Hours Indicates the total runtime of the waterjet motor from its first activation to the most recent shutdown. @@ -1773,7 +1773,7 @@ Enabling or disabling the "Write debug information to a file" debug.txt Enabling or disabling the ability to block a page -#### 1.6.1.5 Use Aitalmac Remote +#### 1.6.1.5 Use AitalMAC Remote Enables or disables the ability to use the AitalMAC remote control for machine operations. @@ -1785,7 +1785,7 @@ Enables or disables the ability to use the AitalMAC remote control for machine o Enabling or disabling the ability check B angle when Z down without Blade -#### 1.6.1.9 Image Position Is Without KINS +#### 1.6.1.9 Image Position Is Without Kins #### 1.6.1.10 Debug Mode @@ -2534,7 +2534,7 @@ Saves the changes made to the configuration settings. ##### 1.6.3.2.3 Cancel -##### 1.6.3.2.4 Ok +##### 1.6.3.2.4 OK ### 1.6.4 Machine Parameter @@ -2704,7 +2704,7 @@ Saves the changes made to the configuration settings. ![Status and Control Panel](/aitalmac-ui/1.10.png) -### 1.10.1 3d Preview +### 1.10.1 3D Preview ### 1.10.2 X View