No, you should not have received two parallel breakout boards in your CNC kit. You can return the extra item using standard shipping with COD. Our apologies for the confusion and the inconvenience.

I will answer the other question as another FAQ. Please check the Customer Service page to see the answer to that question.

If you have difficulty finding the answer, here is a link:
https://www.buildyourcnc.com/FAQ/13636

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I have a 2000 WK 11–3 Z limit switches going to A c10r10 breakout board . Can I also use them as my home position as well. I need The wiring configuration

You can add a limit switch to either the USB or the parallel board. Please refer to the product pages for these items to view wiring diagrams.

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I want to add limit switches but I have no connections on the breakout board. Can I use a usb interface board for the limit switches as well as the parallel port for the running?

You can add a limit switch to either the USB or the parallel board. Please refer to the product pages for these items to view wiring diagrams.

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I want to add limit switches but I have no connections on the breakout board. Can I use a usb interface board for the limit switches as well as the parallel port for the running?

For safety's sake I would recommend a new board because they are inexpensive compared to the electronics that they support. Alternatively, it's possible that the one dead pin is a simple fix, such as a bad connection or solder joint; if you feel comfortable making those repairs then it could be worthwhile to check. Finally, if you are not using all the input pins, you could continue to operate the limit switch on pin 11 and hope for the best.

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I have a breakout board and it appears that the pin 12 connection has failed: when i move my limit switches to pin 11 they work; they don't work on pin 12. Do i need a new breakout board?

You will want to connect the homing switches (which may also serve as your near limit switches) to different input terminals. It's ok to add more limit switches with the home switches, but each home should be on independent inputs. For example, connect home X and any other limit switch to IN1, connect home Y and any other limit switch to IN2, and so on. This will allow you to properly use the "ref all home" button in Mach3.

Additional Information:


Additional Information:
In the instructions (diagram 1) you show all the home switches connected in parallel? But here you say they need to each have their own inputs. "You will want to connect the homing switches (which may also serve as your near limit switches) to different input terminals." I dont see how the second and third axis can go home if the first axis has already closed the parallel circuit unless they back off a bit until the switch opens up again before the next axis goes to home? My machine has no limit switches so I assume they are home switches.

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[575] I have finally got my limit switches wired and working - thank you. Can they also used as homing switches and if so it it just a question of looping the two inputs on the board i.e. the limit and home terminals IN2 to IN3

The e-stop should be wired like a limit switch and can also be within the same limit switch circuit. Use one of the input pins to create the e-stop circuit.

1. Run a wire from the input pin terminal to the e-stop switch red side (one of the two terminals on the red side). The red side is NC (Normally Closed).

2. Run a wire from the other side of the red side of the e-stop switch back to the gnd terminal (or to the next switch - limit switch, NC terminal, then back to gnd, or to the next NC terminal of the next switch, do you see a recursive pattern here?).

The wire that you use for the connections should be shielded and the shielding and any other loose wire within the cable should be tied to gnd.

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Hi - I have wired in a breakout board (with relay) as per suggested wiring instructions (black toe 2X4). I want to wire in an estop but need some guidance on wiring. Also Mach3 is requesting I reset the estop, which suggests its expecting one? Can anyone help? Thanks. Miles

Yes, the Mach3 USB board has two terminals that require 24V connection. Most VFDs have a 24V output that can be used to power this part of the Mach3 USB board.

The V+ and V- on the Mach3 USB is not absolutely necessary to operate the CNC machine/router. The V+ and V- of the Mach3 USB board powers the outputs, inputs, and spindle's speed and control.

Here is the Mach3 USB link for more information:
https://www.buildyourcnc.com/item/electronicsAndMotors-electronic-component-breakout-Mach3-USB-Board

The new YL600 VFD we have in stock may not have this 24V output. There is a 12V terminal, but I have not tested that terminal if it outputs 12V, or if it is a 12V input. If you are only conecting limit switches to the Mach3 USB and need to power that portion, 12V will be sufficient.

I will delve into these aspects in far more detail on video.

Thanks and Merry Christmas to you as well!

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Hey Guys, I have a brand new redleaf and 5x. In the final stages of wiring and wondering a few things. Can I connect the Mach3 USB board V+ V- to my frequency inverter (type YL600-2s-2k20)? If so where? Will your upcoming (part 2)video deal with this as well as final connections for limit switches and stop button? Merry Christmas!

Sure, the USB interface has a place for 4 axes of limit switches.

Each axis can have two limit switches: one for the ++ (positive) end and one for the -- (negative) end. The positive end would be the limit switch at the end of the machine that, say the machine has a 4'x8' area, reaches a bit after the 8 foot mark. The negative end would be the limit switch behind the 0 foot location behind the origin. If the origin is in the middle, the negative would be at a little more than the -4 foot end and the positive would be at a bit more than the +4 foot end. Note that you can have more than one switch on each pin where the NC is connected in serial fashion and the NO is connected in parallel fashion (this can be seen on the diagram in the multiple limits switch section). The software configurations for the limits switches are under File -> Settings -> Limit.

A typical limit switch has three connections on it. These connections consist of COM (common), NC (normally closed) and NO (normally open). The COM would generally go to GND and the NC or the NO would go to the pin. If the NC is used, then the the switch is constantly connected until the switch is pushed (engaged) then the connection from the pin to gnd is broken (open). Use the settings in software to set whether in NC or NO configuration.

Let me know if this information was helpful (or not) by adding information to this question. Thanks.

User response:
Thank you very much for this helpful information. I'm still a little fuzzy on how the 6 limit switches physically connect to each other and to the USB breakout board. You've stated one switch (home) goes to positive and another switch (limit) goes to negative. Are all the GND prongs from all 6 switches connected to each other and going to GND on the breakout board, or no? And the NC prongs, how exactly are they connected to each other? And to the board? There has to be a diagram somewhere shows this visually, no? I don't know how to wire the switches in series or in parallel. I have already physically installed all the switches on the machine and ran the wires to where the board is. Now I just need to know where to plug these wires into the board. Also, taking into consideration that I'm using the Planet CNC software, the only settings I have pertaining to limit switches is "Enable/Disable" for each axis, and the actual limit for each axis. Nothing about NC or NO. Is that only in Mach3?
Thank you.

buildyourcnc response:
On the USB interface, the COM on the switch connects to GND and the NC or NO connects to the input pin (i.e. x++, y--, etc.)

Limit switch configuration is rather difficult to understand, especially with series and parallel. You can think of series as a single wire going from GND to the axis letter input terminal (i.e. X++ or X--). If the wire is broken, then the circuit is open (or the switch is engaged in a normally closed scenario). Normally closed is like an actual wire, and when engaged, the switch "opens" (breaks the wire). This is why we recommend in some systems that you can put many switches in series on a single pin. When one of the switches is engaged (breaking the connection) then the entire circuit of switches is broken and the machine stops.

In a parallel scenario, the state of the circuit is always broken until the one of the switches is engaged and the circuit is then closed or connected. The topology looks like a ladder. All the switches connect to both sides of the ladder and the switches are like the runs of the ladder (the horizontal bars that the feet are placed while climbing). Imagine all of the switches broken in this scenario (normally open). It would be like the ladder could be split in two, but if one of the ladder runs (switches) is closed by engaging it, then that run would connect both sides of the ladder and the two sides of the ladder would have a connection.

There is a diagram on the USB page of the various limit switch configurations. If you need more information (visual and/or otherwise), please let us know and we will immediately add that information to benefit everyone.

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I purchased limit switches from you mounted them on my machine and wire them to the breakout for using pin 12 and the ground on the breakout board, after a few minutes I got a message about a limit switch trip. Am I supposed to use the extra outport on the board instead of the ground?

Sure, the USB interface has a place for 4 axes of limit switches.

Each axis can have two limit switches: one for the ++ (positive) end and one for the -- (negative) end. The positive end would be the limit switch at the end of the machine that, say the machine has a 4'x8' area, reaches a bit after the 8 foot mark. The negative end would be the limit switch behind the 0 foot location behind the origin. If the origin is in the middle, the negative would be at a little more than the -4 foot end and the positive would be at a bit more than the +4 foot end. Note that you can have more than one switch on each pin where the NC is connected in serial fashion and the NO is connected in parallel fashion (this can be seen on the diagram in the multiple limits switch section). The software configurations for the limits switches are under File -> Settings -> Limit.

A typical limit switch has three connections on it. These connections consist of COM (common), NC (normally closed) and NO (normally open). The COM would generally go to GND and the NC or the NO would go to the pin. If the NC is used, then the the switch is constantly connected until the switch is pushed (engaged) then the connection from the pin to gnd is broken (open). Use the settings in software to set whether in NC or NO configuration.

Let me know if this information was helpful (or not) by adding information to this question. Thanks.

User response:
Thank you very much for this helpful information. I'm still a little fuzzy on how the 6 limit switches physically connect to each other and to the USB breakout board. You've stated one switch (home) goes to positive and another switch (limit) goes to negative. Are all the GND prongs from all 6 switches connected to each other and going to GND on the breakout board, or no? And the NC prongs, how exactly are they connected to each other? And to the board? There has to be a diagram somewhere shows this visually, no? I don't know how to wire the switches in series or in parallel. I have already physically installed all the switches on the machine and ran the wires to where the board is. Now I just need to know where to plug these wires into the board. Also, taking into consideration that I'm using the Planet CNC software, the only settings I have pertaining to limit switches is "Enable/Disable" for each axis, and the actual limit for each axis. Nothing about NC or NO. Is that only in Mach3?
Thank you.

buildyourcnc response:
On the USB interface, the COM on the switch connects to GND and the NC or NO connects to the input pin (i.e. x++, y--, etc.)

Limit switch configuration is rather difficult to understand, especially with series and parallel. You can think of series as a single wire going from GND to the axis letter input terminal (i.e. X++ or X--). If the wire is broken, then the circuit is open (or the switch is engaged in a normally closed scenario). Normally closed is like an actual wire, and when engaged, the switch "opens" (breaks the wire). This is why we recommend in some systems that you can put many switches in series on a single pin. When one of the switches is engaged (breaking the connection) then the entire circuit of switches is broken and the machine stops.

In a parallel scenario, the state of the circuit is always broken until the one of the switches is engaged and the circuit is then closed or connected. The topology looks like a ladder. All the switches connect to both sides of the ladder and the switches are like the runs of the ladder (the horizontal bars that the feet are placed while climbing). Imagine all of the switches broken in this scenario (normally open). It would be like the ladder could be split in two, but if one of the ladder runs (switches) is closed by engaging it, then that run would connect both sides of the ladder and the two sides of the ladder would have a connection.

There is a diagram on the USB page of the various limit switch configurations. If you need more information (visual and/or otherwise), please let us know and we will immediately add that information to benefit everyone.

Click the link to add information to this solution:
I have nearly completed the CNC machine from the book, but I am using it with a USB breakout board, and have no idea how to wire the 6 limit switches to the board. I'm having difficulty following the diagram on the USB breakout board screen. Can someone please help me?

Ok, I will check the YL600 documentation Monday 4/3 and provide the answer here.

Additional Information:


Additional Information:
I also received one of these and the button labels do not even match your programming instructions as stated on your web set. Please provide updated instruction to match the model shipped with the correct button names to press in The programming process.

Additional Information:
7/15/17 - I have exact problem. I do not see the solution posted???

Additional Information:
Mine is a 2.2Kw YL-620 connected to a 1.5Kw spindle.

Code Address Function Set Range &Function Explanation Factory Setting User Set Vendor Suggested As shipped Code Address Decimal
P00.00 0 Main Frequency 0-120HZ(400HZ） 50.0HZ 　400 60 399.6 P00.0 0
P00.01 1 Start / stop command source 0: Operator board 0 0　 0 P00.1 1
1：From external end control Electric machinery,operation panel STOP key effective
2：From external end son control Electric machinery,operation panel STOP key invalid
3：from (Modbus Rs485) control Electric machinery
4：By user application program control Electric machinery
P00.02 2 Reserved 　 0 　 0 P00.2 2
P00.03 3 Stopping Mode 0：Decelerating stop 0 0　 1 P00.3 3
1：Coasting stop 10
2：DC brake stop 0.2
P00.04 4 VF:Highest output frequency 1.0-120.0HZ(400HZ） 50.0HZ 400 60 400 P00.4 4
P00.05 5 VF:Maximum Voltage Output Frequency 5.0-120.0HZ(400HZ） 50.0HZ 400 60 400 P00.5 5
P00.06 6 VF:Highest output Voltage 10.0%-150.0% 100.00% 100.00% 100.00% 100 P00.6 6
P00.07 7 VF:Middle Frequency 1.0-120.0HZ(400HZ） 3.0Hz 3.5Hz 3.0Hz 3.5 P00.7 7
P00.08 8 VF:Middle Voltage 10.0%-100.0% 10% 20% 10% 10 P00.8 8
P00.09 9 VF:Min Frequency 0-120.0HZ(400HZ） 0.2HZ 0.2Hz 0.2Hz 0.2 P00.9 9
P00.10 10 VF:Min Voltage 0%-100.0% 5% 10.00% 5.00% 5 P00.10 10
P00.11 11 Analog Input quantity 1 Regulation Multistage velocity 0%-100% 100 100 100 100 P00.11 11
P00.12 12 VF :Curve Setting 0-4 0 0 P00.12 12
P00.13 13 Parameter Lock 0: lnvalid 0 0 P00.13 13
1: Valid
10: Restore the factory setting No other function
P00.14 14 Reserved 0 0 P00.14 14
P00.15 15 Power on Time prohibit External end son Start-up 0:Power on time,allow External end input effective level,start-up Electric machinery 0 0 P00.15 15
1:Power on time,Not allow
P00.16 16 0: FWD(X5)yes,Positive run the 0 P00.16 16
1: REV(X6) Determine direction : Open Yes
2:X_EF=EF,X_REV(X5)_DIR=DIR,FWD(X6)=
3: Stop ,FWD(X5) turn off Instantaneous
4: FWD(X5) turn off Instantaneous
5: FWD(X5) turn off Instantaneous
6: Stop ,FWD(X5) turn off Instantaneous
7: REV(X6)When open,FWD(X5)Start-up
P00.17 17 Many function input X1 function Choice ####################################### ####################################### 1 1 P00.17 17
P00.18 18 Many function input X2 function Choice 1.0HZ 1 P00.18 18
P00.19 19 Many function input X3 function Choice 1 P00.19 19
P00.20 20 Many function input X4 function Choice 1 P00.20 20
P00.21 21 External Terminal rise/Slow down increment 0-120HZ(400HZ) 1.0HZ 1 P00.21 21
P00.22 22 External Terminal rise/Slow down time interval 0.2 0.2 P00.22 22
P00.23 23 Physics amount display Proportion constant 0-999.9% 100.00% 100 P00.23 23
P00.24 24 After power supply, display project choice 0: Display current target frequency 0 0 P00.24 24
1:Display Electric machinery run frequency.
2:Display Electric machinery run current.
3:Display input AC voltage
4:Display mother Line voltage
5:Display output voltage
6:Display speed paragraph Number SP x
7:Display inverter temperature t xx
8:Display input signal X1-X3/output signal
9:Display user variable
10:Display user Count value
11:Display temporary debugging variable
12:Display automatic multi segment run step and time
P00.25 25 Display project automatic Return delayed time (10/S) 0:No,Automatic return;1-6delayed 10-60S Back Return 1 1 P00.25 25
P01.00 256 REV Rotation Select 0: Rev Run Enable 0 0 P01.0 256
1: Rev Run Forbidden 0
P01.01 257 Electric machinery Reversing wait for time 0 P01.1 257
P01.02 258 Deceleration Prevention overvoltage setting(%) 130 130 P01.2 258
P01.03 259 Accelerated Prevention overcurrent setting(%) 130 130 P01.3 259
P01.04 260 Overcurrent Set up (%) 200 200 P01.4 260
P01.05 261 Overload protection Set up (%) 130 130 P01.5 261
P01.06 262 Overload protection time Set up (s) 120 120 P01.6 262
P01.07 263 Undervoltage protection Set up (%) 80 80 P01.7 263
P01.08 264 Overvoltage protection Set up (%) 150 150 P01.8 264
P01.09 265 After shutdown, start DC Brake voltage Setup (%) 15 15 P01.9 265
P01.10 266 After shutdown, End DC Brake voltage Setup (%) 0 0 P01.10 266
P01.11 267 After shutdown, DC Braking Time Set up 2 2 P01.11 267
P01.12 268 After shutdown, DC Braking Initial Frequency Set up 0.6 0.6 P01.12 268
P01.13 269 Before start , input DC brake voltage set up (%) 20 20 P01.13 269
P01.14 270 Before start , End DC Brake voltage Set up (%) 15 15 P01.14 270
P01.15 271 Before start , DC Braking Time Set up 3 3 P01.15 271
P01.16 272 Direct start Initial frequency (Improve starting torque ) 100 100 P01.16 272
P01.17 273 Direct start Initial frequency Hold time 0 0 P01.17 273
P01.18 274 power failure frequency decline 80 80 P01.18 274
P01.19 275 The power down frequency decline rate 5 5 P01.19 275
P01.20 276 Restart No load time 10 10 P01.20 276
P01.21 277 Restart voltage rise time 200 200 P01.21 277
P02.00 512 When speed up torque will increased 　 100　 100 100 60 P02.0 512
P02.01 513 Deceleration time - Torque Boost 　 100　 100 100 60 P02.1 513
P02.02 514 Accelerate curve Choice 0　 0 P02.2 514
P02.03 515 Deceleration curve Choice 0　 0 P02.3 515
P02.04 516 Avoid the f requency 1 20 400 P02.4 516
P02.05 517 Avoid the f requency 2 30 30 P02.5 517
P02.06 518 Avoid the f requency 3 　 40 40 P02.6 518
P02.07 519 Avoid the f requency Width 　 0 0 P02.7 519
P02.08 520 Window frequency 1 45 45 P02.8 520
P02.09 521 Window frequency 2 50 50 P02.9 521
P02.10 522 ? 400 P02.10 522
P03.00 768 RS485 Communication Baud Rate 0: 1200Bps 5 4 P03.0 768
1: 2400Bps
2: 4800Bps
3: 9600Bps
4: 19200Bps
5: 38400Bps
6: 57600Bps
P03.01 769 RS485 Communication Addresses 1-254 10 10 P03.1 769
P03.02 770 0: 8 bit data, 1 stop bits, odd parity 2 2 P03.2 770
1: 8 bit data, 1 stop bits, parity check
2: 8 bit data, 1 stop bit, no parity
3: 8 bit data, 2 stop bits, odd parity
4: 8 bit data, 2 stop bits, parity check
5: 8 bit data, 2 stop bit, no parity
P03.03 771 Communication error handling 0 P03.3 771
P03.04 772 Communication error tolerance time 20 P03.4 772
P03.05 773 4-20mA Break detection time 0 P03.5 773
P03.06 774 Panel potentiometer,Lower limit of AD norm 3 P03.6 774
P03.07 775 Panel potentiometer,Upper limit of AD specification 1020 1015 1015 P03.7 775
P03.08 776 Panel potentiometer, frequency given of lower limit 0.0HZ 0 0 P03.8 776
P03.09 777 Panel potentiometer, frequency given of Upper limit 0-120HZ(400HZ） 60.0HZ 400 　60Hz 400 P03.9 777
P03.10 778 Analog lnput 1 AD lower limit 0-1023 3.0Hz 　60Hz 3 P03.10 778
P03.11 779 Analog lnput 1 AD Upper limit 0-1023 1020 1010 1010 P03.11 779
P03.12 780 Analog lnput 1 frequency given lower limit 0.0HZ 0 P03.12 780
P03.13 781 Analog lnput 1 frequency given Upper limit 60.0HZ 400 400 P03.13 781
P03.14 782 Analog lnput 2 AD lower limit 3.0Hz 3 P03.14 782
P03.15 783 Analog lnput 2 AD Upper limit 1020 1010 1010 P03.15 783
P03.16 784 Analog lnput 2 frequency given lower limit 0.0HZ 0 P03.16 784
P03.17 785 Analog lnput 2 frequency given Upper limit 60.0HZ 60 P03.17 785
P03.18 786 Analog output correlation 0 0 P03.18 786


P03.19 787 Analog output gain setting 100 100 P03.19 787
P04.00 1024 Mo analog multiplier output frequency multiplier 10 10 P04.0 1024
P04.01 1025 Mo1 Function Options 0 0 P04.1 1025
P04.02 1026 Mo2 Function Options 1 1 P04.2 1026
P04.03 1027 Multi-function Relay 1 Function selection 0:fault Yes Electric , otherwise power failure 0 2 2 2 P04.3 1027
P04.04 1028 Multi-function Relay 2 Function selection 1:Running Yes Electric ,otherwise power failure 3 3.0Hz 3 P04.4 1028
2: Reserved
3: Arbitrary frequency arrival Time, have Electric,Related to P02-10 settings
4: , The power down Time,have Electric
5:, low voltage Time, have Electric
6:, Overvoltage Time, have Electric
7: Overcurrent Time, have Electric
8: Nonzero velocity Time,have Electric
9:, DC brake Time, have Electric
10: Over torque Time, have Electric
11: External interrupt fault Time, have
12: Forward Time, have Electric
13: Reversal Time, have Electric
14: Move Time, have Electric
15: Accelerate Time, have Electric
16: Deceleration Time, have Electric
17: Constant speed Time, have Electric
18:X1 close Time, have Electric
19:X2 close Time, have Electric
20:X3 close Time, have Electric
21:X4 close Time, have Electric
22:X5 close Time, have Electric
23:X6 close Time, have Electric
24: Forward and bus voltage greater than 400V Time, have Electric
25: Reverse and bus voltage greater than 400V Time, have Electric
P04.05 1029 Multi-function Relay 1 Action close Delayed 0-65.5 S 0 0 P04.5 1029
P04.06 1030 Multi-function Relay 1 disconnect delay action 0-65.5 S 0 0 P04.6 1030
P04.07 1031 Multi-function Relay 1 Action close Delayed 0-65.5 S 0 0 P04.7 1031
P04.08 1032 Multi-function Relay 1 disconnect delay action 0-65.5 S 0 0 P04.8 1032
P04.09 1033 Stall rotor detection time 0-65.5 S 1 1 P04.9 1033
P04.10 1034 Switch amount (Di) sampling time 0-1000mS 8 24 24 P04.10 1034
P04.11 1035 Stopping Mode 0:Decelerating stop 0 0 P04.11 1035
1:Coasting stop
P05.00 1280 PID Output Upper limit frequency 50 50 P05.0 1280
P05.01 1281 PID Output lower limit frequency 25 25 P05.1 1281
P05.02 1282 PID Given Source 0 0 P05.2 1282
P05.03 1283 PID Values Given 0.2 0.2 P05.3 1283
P05.04 1284 PID Output characteristic(FOR /REV) 0 0 P05.4 1284
P05.05 1285 PID Output characteristic (FOR/REV) 0 0 P05.5 1285
P05.06 1286 PID Proportional Gain 0-100.0 50 50 P05.6 1286
P05.07 1287 PID Integration Time Ti 0-100.0 0-100.0 50 50 P05.7 1287
P05.08 1288 PID Derivative Time Td 0-100.0 0-100.0 50 50 P05.8 1288
P05.09 1289 PID Deviation Limit 0-50.0 5 5 P05.9 1289
P05.10 1290 PID Integral upper limit 50 50 P05.10 1290
P05.11 1291 PID Given Change Time 0-600.0 1 1 P05.11 1291
P05.12 1292 PID Feedback Filter Time 0 0 P05.12 1292
P06.00 1536 Acceleration Time 0　 0 P06.0 1536
P06.01 1537 Accel.Time 1 0.1-6553.5 5.0 9 　5.0 5 P06.1 1537
P06.02 1538 Decel. Time 1 0.1-6553.5 5.0 8.6 　5.0 5 P06.2 1538
P06.03 1539 Accel.Time 2 0.1-6553.5 0.1-6553.5 2 2 P06.3 1539
P06.04 1540 Decel. Time 2 0.1-6553.5 0.1-6553.5 2 2 P06.4 1540
P06.05 1541 Accel.Time 3 0.1-6553.5 0.1-6553.5 2 2 P06.5 1541
P06.06 1542 Decel. Time 3 0.1-6553.5 0.1-6553.5 2 2 P06.6 1542
P06.07 1543 Accel.Time 4 0.1-6553.5 0.1-6553.5 2 2 P06.7 1543
P06.08 1544 Decel. Time 4 0.1-6553.5 0.1-6553.5 2 2 P06.8 1544
P06.09 1545 Accel.Time 5 0.1-6553.5 0.1-6553.5 2 2 P06.9 1545
P06.10 1546 Decel. Time 5 0.1-6553.5 0.1-6553.5 2 2 P06.10 1546
P06.11 1547 Accel.Time 6 0.1-6553.5 0.1-6553.5 2 2 P06.11 1547
P06.12 1548 Decel. Time 6 0.1-6553.5 0.1-6553.5 2 2 P06.12 1548
P06.13 1549 Accel.Time 7 0.1-6553.5 0.1-6553.5 2 2 P06.13 1549
P06.14 1550 Decel. Time 7 0.1-6553.5 0.1-6553.5 2 2 P06.14 1550
P06.15 1551 Accel.Time 8 0.1-6553.5 0.1-6553.5 2 2 P06.15 1551
P06.16 1552 Decel. Time 8 0.1-6553.5 0.1-6553.5 2 2 P06.16 1552
P06.17 1553 Jog Acceleration Time 0.1-6553.5 0.1-6553.5 2 2 P06.17 1553
P06.18 1554 Jog Deceleration Time 0.1-6553.5 0.1-6553.5 2 2 P06.18 1554
P07.00 1792 Frequency 1 0-120HZ(400HZ) 50HZ 50 50 P07.0 1792
P07.01 1793 Frequency 2 50HZ 45 45 P07.1 1793
P07.02 1794 Frequency 3 50HZ 40 40 P07.2 1794
P07.03 1795 Frequency 4 50HZ 35 35 P07.3 1795
P07.04 1796 Frequency 5 50HZ 30 30 P07.4 1796
P07.05 1797 Frequency 6 50HZ 25 25 P07.5 1797
P07.06 1798 Frequency 7 50HZ 20 20 P07.6 1798
P07.07 1799 Frequency 8 50HZ 15 15 P07.7 1799
P07.08 1800 Frequency source selection 1 0: Operator board (parameter: P03.06~P03.09) 0 0 P07.8 1800
P07.09 1801 Frequency source selection 2 1: Pre-set Freq, P00.00 Set frequency value,Operation panel keyboard,Can be set directly 2 2 P07.9 1801
P07.10 1802 Frequency source selection 3 2:No. X paragraph frequency P07.00~P07.07 2 2 P07.10 1802
P07.11 1803 Frequency source selection 4 3: Analog Input. :P03.10~P03.13) 2 2 P07.11 1803
P07.12 1804 Frequency source selection 5 4: external simulation amount 2 (VI2) 2 2 P07.12 1804
P07.13 1805 Frequency source selection 6 5: (Modbus Rs485)Given frequency 2 2 P07.13 1805
P07.14 1806 Frequency source selection 7 6: User application program, given frequency 2 2 P07.14 1806
P07.15 1807 Frequency source selection 8 7:( Pid)Output frequency 2 2 P07.15 1807
Other: Reserved
Note:three control methods (P07.08) 1808 1.The motor speed is controlled by the operating panel P07.16 1808
2.Motor speed control by external terminals (Potentiometer 10K). P00.01 set to 1, P07.08 set to 3
3.Motor speed control by external terminals. P00.01 set to 1,P07.08 set to 1.
P07.16 1809 Jogging Frequency FORWARD 0-120HZ(400HZ) 15.0HZ 15 P07.17 1809
P07.17 2048 Jogging Frequency REV 0-120HZ(400HZ) 15.0HZ 13.0Hz 13 P08.0 2048
P08.00 2049 Automatic many paragraph Running: Running direction Binary data format to set the direction of operation, see (the automatic multi segment operation, the operation of the direction set table) 0　 0 P08.1 2049
P08.01 2050 Automatic many paragraph Running: mode Choice 0:Automatic multi segment operation is invalid; 0 0 P08.2 2050
1:After execution complete,Stop;
2:After execution complete,Keep the last running state,Continued running;
3:After execution complete, Repeated execution.
P08.02 2051 Automatic many paragraph Running time Units:S/M 0:S;1:M 0 0 P08.3 2051
P08.03 2052 Automatic many paragraph Running: No.1 paragraph Running time Automatic multi-section run time,Set up Section speed run time。Time units are determined by P08.02 Decision。Set run is 0,Indicates that this section is not executed. 10 1 1 P08.4 2052
P08.04 2053 Automatic many paragraph Running: No.2 paragraph Running time 10 1.5 1.5 P08.5 2053
P08.05 2054 Automatic many paragraph Running: No.3 paragraph Running time 10 1 1 P08.6 2054
P08.06 2055 Automatic many paragraph Running: No.4 paragraph Running time 10 1.5 1.5 P08.7 2055
P08.07 2056 Automatic many paragraph Running: No.5 paragraph Running time 10 1 1 P08.8 2056
P08.08 2057 Automatic many paragraph Running: No.6 paragraph Running time 10 1.5 1.5 P08.9 2057
P08.09 2058 Automatic many paragraph Running: No.7 paragraph Running time 10 1 1 P08.10 2058
P08.10 2304 Automatic many paragraph Running: No.8 paragraph Running time 10 1.5 1.5 P09.0 2304
P09.00 2305 frequency Range(%) 0-200% 0 0 P09.1 2305
P09.01 2306 frequency wave Range(%) 0-400% 200 30 30 P09.2 2306
P09.02 2307 frequency Rise time(S) 0.1-999.9 S 6.0 S 6 P09.3 2307
P09.03 2560 frequency decline time(S) 0.1-999.9 S 5.0 S 5 P10.0 2560
P10.00 2561 Counter reload,value 1000 1000 P10.1 2561
P10.01 2562 Counter current value 0 0 P10.2 2562
P10.02 2563 Timer reload,value 1000 1000 P10.3 2563
P10.03 2816 Timer current value 0 0 P11.0 2816
P11.00 2817 Output Status 1 1 P11.1 2817
P11.01 2818 Output Voltage (V) 0 0 P11.2 2818
P11.02 2819 Output Current (A) 5 5 P11.3 2819
P11.03 2820 Output Frequency (Hz) 50 50 P11.4 2820
P11.04 3072 Current Heatsink Temperature 25 25 P12.0 3072
P12.00 3073 Rated Motor Current 5 5 P12.1 3073
P12.01 3074 Rated Motor Voltage 220 220 P12.2 3074
P12.02 3075 Motor Pole number 2-100 2 2 P12.3 3075
P12.03 3076 Motor no-load current 10 10 P12.4 3076
P12.04 3077 Motor no-load current detection time(S) 10 10 P12.5 3077
P12.05 3078 Converter rated current(A) 5 5 P12.6 3078
P12.06 3079 Converter rated Voltage(V) 220 220 P12.7 3079
P12.07 3080 DC bus output voltage% 140 130 P12.8 3080
P12.08 3081 Heat sink over temperature protection point 70 75 P12.9 3081
P12.09 3082 Radiating fin temperature sensor configuration 1 1 P12.10 3082
P12.10 3083 Abnormal reset implement wait time 120 120 P12.11 3083
P12.11 3084 Fan Function Pattern 0:Motor running tine, start fan; 1 1 P12.12 3084
1:When the fan operating temperature (P12.12) is exceeded,Instant start fan; When the temperature is lower than the fan temperature point,Delay about 1 minutes to close the fan;
2:Unconditional forced start fan;
3:Fan Inoperation;
P12.12 3085 Cooling fan operating temperature 55 45 50 P12.13 3085
P12.13 3086 Fan Testing 0 0 P12.14 3086
P12.14 3087 Bypass relay closed detection 0 0 P12.15 3087
P12.15 3088 Bypass Relay delay time 1.5 1 P12.16 3088
P12.16 3089 Power on delay timer initial value(S) 50 50 P12.17 3089
P12.17 3090 Electric current sensor To configure 1 1 P12.18 3090
P12.18 3091 Automatic stable pressure function Choice 1 1 P12.19 3091
P12.19 3092 PWM Frequency 2.0-15.0KHZ (110V13.0KHZ 220V11.0KHZ 380V6.0KHZ) 8.0KHZ 13.0KHz 13 P12.20 3092
P12.20 3328 SVPWM Pattern 0:Three-phase asynchronous motor, 0 0 P13.0 3328
1:Two-phase asynchronous motor (Single-phase motor, 90 degree phase difference,Starting capacitor)
P13.00 3329 103 P13.1 3329
P13.01 3330 600 P13.2 3330
P13.02 3331 1 P13.3 3331
P13.03 3332 16.24 P13.4 3332
P13.04 3333 1 P13.5 3333
P13.05 3584 0 P14.0 3584
P14.00 3585 35 P14.1 3585
P14.01 3586 0.2 P14.2 3586
P14.02 3587 1 P14.3 3587
P14.03 3588 0 P14.4 3588
P14.04 3589 0 P14.5 3589
P14.05 3590 100 P14.6 3590
P14.06 3591 1900 P14.7 3591
P14.07 3592 2000 P14.8 3592
P14.08 3593 59999 P14.9 3593
P14.09 3594 5 P14.10 3594
P14.10 3595 20 P14.11 3595
P14.11 3596 0 P14.12 3596
P14.12 3597 0 P14.13 3597
P14.13 3598 0 P14.14 3598
P14.14 3599 0 P14.15 3599


Additional Information:
Sorry, that is a paste from a spread sheet, you may have to do some formatting or paste it into a spread sheet to see it better...

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I will definitely do that. Thank you so much for providing the information!!

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I also have this problem with a yl620. Is there a solution?

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Is there a wiring diagram for the 110v units. My came with a 220 volt booklet.

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my unit also came with instructions for a 220 unit. I need a 110 wiring diagram.

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These instructions are lame at best, a friend of mine ordered one of these to install on a knife grinder that I built for him, and I proceeded to setup the unit, upon connecting it to the motor, it runs the motor, but hunt's at the lower speeds, and the setting I am looking for just isn't in the list, there's some settings in the 14's that don't say what there for, can anyone help?

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I received a VFD 110v yl600-2s-2k20 p 110v with 220v instructions, also the connectors on the VFD dose not match any wiring configuration you have.

BYCNC Response:
This is correct. You will need to use a method appropriate for the software you are using. Also remember that NC switches are typically wired in series, while NO switches are normally wired in parallel.

User Response:
I am using the cnc planet software for your USB board. Are the limit configurations in this software?

BYCNC Response:
Yes, Planet CNC software is compatible with the use of limit switches. Configuration information will depend on your specific application. You can view Planet CNC's information here: http://www.planet-cnc.com/files/CNCUSBController.pdf

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LIMIT SWITCHES FOR AXIS. THE PRINT SHOWS THAT YOU CAN WIRE LIMITS EITHER N.O. OR N.C. SO IF THIS IS CORRECT I WOULD NEED TO TELL BOARD IN SOFTWARE HOW LOOK AT THESE LIMITS, I'M GOING GET AN INPUT LOOSE DEPEND ON IT.

The 5V power required for the breakout board can be a simple USB male to male cable, that will connect from your computer to the board itself.
Now adding a external power supply make sure that it does not exceed a total of 5V and the standard 500 MilliAMP - 1 A.

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I have a YDH-18-5 Power Supply AC Input:100-240v 47-63Hz, Ouput: 5v - 2A and need to know if its safe to use with the Parallel Breakout Board.

NC mechanical switch configuration is supported. You can download the manual from this page (Mach4 plugin and manuals):
https://buildyourcnc.com/item/electronicsAndMotors-electronic-component-breakout-Mach4-mach3-USB-ethernet-Board

The pokeys57CNC controller has input terminals and pins for limit switches on each of the 8 axes. There are three separate inputs per axis, two for the actual limits of that axis, and one for the home position.

Connect each switch between the GND terminal and its respective axis limit terminal/pin. For instance, the limit switch will typically have three leads, COM, NC, and NO. In an NC configuration, the NC connects to the terminal/pin, say, Axis 1 lim +, and the COM connects to the GND terminal.

In Mach4, in the new device wizard, make sure to specify the correct option on the home and limit switches that matches the machine configuration.

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Hello, I am trying to configure Home and Limit switches using the Pokeyes57cnc and NC switches. I am confused on the procedure of setting this up. wiring to the board and setting up in Mach4. Can you direct me to a tutorial or offer some suggestions? Thanks Dale

Have you tried a different input pin?

Customer response:
I've tried all pins: 10, 11, 12, and 13. I get the same non-response in each case.

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There may be a problem with the board. If you are using our parallel breakout board, we can ship you a replacement (call us), otherwise, you will need to determine the problem with the vendor of the breakout board you are using.

Additional Information:
I have tried 3 different breakout boards from 3 different providers and they all do the same thing My limit switches are microswitches wired NC with each axis wired to the BO Board. I have checked each circuit and all is OK to the BO board. each circuit has continuity at the board and when any switch is pressed the circuit breaks. Mach 3 does not recognise that the switches are even there. They are configured as active low Do you have a suggestion.

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I'm having trouble getting Mach3 to recognize my limit switches. I've eliminated everything back to the breakout board. I can directly connect Input 10 to GND on the breakout board while Mach3 is in autorecognize mode and Mach3 doesn't acknowledge anything.

BYCNC Response:
This is correct. You will need to use a method appropriate for the software you are using. Also remember that NC switches are typically wired in series, while NO switches are normally wired in parallel.

User Response:
I am using the cnc planet software for your USB board. Are the limit configurations in this software?

BYCNC Response:
Yes, Planet CNC software is compatible with the use of limit switches. Configuration information will depend on your specific application. You can view Planet CNC's information here: http://www.planet-cnc.com/files/CNCUSBController.pdf

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Limit switches for axis. The print shows that you can wire the limits either n.o. or n.c. so if this is correct I would need to tell the board in the software how to look at these limits, I'm either going to get an input or loose an input depend on how i wire it.

A parallel to USB adapter will not work. You will need to use a USB interface like the ones below:

Mach3 USB interface:
https://www.buildyourcnc.com/item/electronicsAndMotors-electronic-component-breakout-Mach3-USB-Board

Poeys57CNC Interface:
https://www.buildyourcnc.com/item/electronicsAndMotors-electronic-component-breakout-Mach4-mach3-USB-ethernet-Board

Additional Information:
To answer the question in more detail, the parallel port is actually an extension straight from the CPU and is also called the GPIO (General Purpose I/O) pins. These pins carry signals independently, hence the description as being a parallel port.

The stepper motor driver receives a pulse train (series of pulses). A single pin on the parallel port sends a pulse train to one stepper motor driver and stepper motor for a single axis. Another pin on the parallel port sends a pulse train to another stepper motor driver on another axis. This happens simultaneously as with the direction signals for each axis.

If a parallel port is adapted through a USB (using an adapter), the parallel port cannot have these signals happen in a simultaneous fashion and will cause the stepper motors of a CNC router or machine to be very clunky, if it works at all. To elaborate, the computer sends an instruction to the USB to send a high signal to pin 1, so it does, then another signal to pin 2, so it does. This is happening one after another. The speed at which this happens is reduced dramatically, and the position of one axis may now be out of sync to another axis.

The reason the USB interfaces (linked above) work is that the USB delivers broad instructions to the interface (to a microcontroller) and the interface parses the instructions and outputs simultaneous signals to the stepper motor drivers.

Hope this helps.

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My computer doesn't have a parallel port connection. Can I use a usb to parallel port cable to communicate with my breakout board?

Any of the following power supplies will be fine for powering the Mach3 USB controller:
https://www.buildyourcnc.com/item/24v

however, the limit switches do not need high current, so the following power supply is sufficient for the task of connecting limit switches:
https://www.buildyourcnc.com/item/electronicsAndMotors-power-supply-24v-1a-dc

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What power supply do you recommend for the spindle and limit switches if I buy the USB Mach3 breakout board?

Yes, absolutely. If you need two motors for a single axis, you will want to use the same terminals for pulse and direction from the breakout board.

More specifically, you will wire the step/pulse pin to both drivers, and the direction pin to both drivers. If the motors need to turn in different directions, simply swap the A and B coil connections on one of the motors.

Additional Information:
i have checked the cnc machine for any flex and there is none but i still cannot cut circles they end up square.have checked calibration and it is correct but if i run at 4000 mm feed all comes out correct but if i change feed to say 2000 mm it makes the part small, like in tiny.

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I'm going to use 2 stepper motors for my X-axis. Can I use the same connections on the B/O board to do this knowing I will need 2 separate driver boards.

The datasheet for the parallel breakout board is here:
https://www.buildyourcnc.com/item/electronicsAndMotors-parallel-breakout-relay#prettyPhoto/2/

The datasheet for the USB interface is here:
https://www.buildyourcnc.com/item/electronicsAndMotors-electronic-component-USB-Controller-Breakout#prettyPhoto/2/


Additional Information:
20

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I need wiring instructions for the breakout board you sent yesterday. It is not like the one in the videos and I don't know where to connect the 5V. No data sheet or anything.