Fixed thread cutting cycle End face G32

G32 Fixed thread cutting cycle: End face

        

[Command format]

          G32 X__ Z__ K__ (E__) (I__) (L__) F__ (C__)

          X: Coordinates of ending point of end face thread cutting

          Z: Thread cutting dimension for each thread cutting

          F: Thread pitch instruction (F/J pitch if J is instructed)

          K: Difference between start and end points for taper thread cutting (If not instructed, K=1.)

             When the value is plus, upward taper, while downward taper then it is a minus value.

          A: Taper angle from the axis parallel to Z axis   (Instruct K or A only.)

          E: Pitch change per pitch for variable pitch thread cutting    (If not instructed, E=0.)

          I: X-axis shift distance at thread cutting start point    (If not instructed, I=0.)

          L: Thread overcutting distance (If not instructed, L is equal to one pitch at start of thread cutting.)

             This is valid when thread cutting chamfering M code (M23) is instructed.

          J: Number of threads at the distance instructed by F (If not instructed, J=1.)

          C: Phase difference of thread cutting (If not instructed, C=0.)

          

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How to make Thread Program In G32 Fanuc Machine

Thread Programming : -  (G32)

          Function and purpose:-

                   The G32 command control the federate of the tool in synchronization with the spindle rotation and so this enables both the straight and scrolled thread cutting of constant leads and the continuous thread cutting.

         

          Detailed Description:-

1.   Constant surface speed control function should not be used here.

2.   The spindle speed should be kept constant throughout from the Roughing until Finishing.

3.    When a threading command is programmed  during tool nose R compensation ,the compensation is temporarily cancelled and the threading executed.

4.  The threading command waits for the single rotation synchronization signal of the rotary encoder and start movement.

              Notes:-

The number of thread in the long axis direction is assigned as the number of thread per inch

Programming Format:-

          Straight thread:-

                   G00 X__                (  Thread cutting Diameter )

                   G32 Z__ F__          ( Thread Length  &  F= pitch )

                   G00 X__                ( X axis Position return )

          Taper thread:-

                   G00 X__

                   G32 X__ Z__ F__

                   G00 X__

Example:-

M20 x 1.5 P x 4MM Length

         

( OD THREAD )

N1 G28 U0.0 W0.0 ;         ( Home Position )

N2 G00 T0101 ;               ( Number One Tool Selection )

N3 G97 S500 M03;            ( Spindle Speed And Direction Selection )

N4 G00  X22.0 Z1.0 M08; ( safe position  & coolant on )

N5 G00 X18.50       ;        ( Thread cutting point X Axis )

N6 G32  Z-4.00 F1.5;       ( Thread cutting 4MM length )

N7 G00 X22.0;                 ( Position Return )

N8 M09 M05 ;                  ( coolant off , spindle stop )

N9 G28 U0.0 W0.0;          ( Home Position Return )

M30;                                ( Program End )

%

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About Thread or what is mean by thread?

Threading:-

Out of different fastening process threading is one. This process is widely used because it doesn’t join two parts permanently giving the flexibility of disassembling them when needed

What is a Thread?

 A thread is a raised, helical rib or ridge around the exterior of a cylindrically shaped object or the interior of a hole. Common threaded parts include screws, nuts, and bolts. Threads have two basic applications: fastening and the transfer or control of motion

Application:-

 Threads have two basic applications: the transfer or control of motion and fastening

Thread is one of the most used processes in mechanical field. In everyday life we come across through many type of components that have a thread in it. Take example of a pen cap or a water bottle etc.

Understanding a thread:

v  The crest is the peak or top of the thread ridge that lies between two flanks. Its size and shape may vary depending on the thread type.

v  The flank is an angled side of a thread. Threads have two flanks.

v  The root is the bottom of the thread that lies between the flanks. Its size and shape also may vary depending on the thread type.

Type of thread:-

Depending on Geometry thread is classified into two categories. A) Straight threads B) taper thread.

Straight threads can be classified into single start or multi start threads.

Important parameters on the thread:-

• v  The pitch point is the position on the thread where the distance between the flanks is equal in both the ridge and the groove.


• v  The pitch diameter is the measured distance between the pitch points in the groove between the threads. It is one of the most important dimensions in thread inspection.


• v  The depth is the length of the vertical space from the root to the crest of a thread.


• v  The major diameter is the distance between the crests of a thread. It is the widest diameter on a thread.


• v  The minor diameter is the distance between the roots of a thread. It is the smallest diameter on a thread.


• v  Thread form which is the shape of the thread example 90 degree, 60 degree threads etc.

Start, Pitch, and Lead

Start:-

 Start refers to the number of different individual threads that wrap around the cylinder. The number of threads equals the number of starts. It means how many start points are there in a thread.

Pitch:-

The distance from one thread crest to the next. For threads manufactured in inches, pitch is expressed in inches as a fraction. It is not the number of threads per inch, but the number "one" divided by the number of threads per inch. For metric threads, pitch is expressed in millimeters.

Lead:-

Lead is the distance that a screw travels in one revolution. This distance is equal to the pitch of the screw multiplied by the number of starts on the screw. On a single-thread screw, the lead equals the pitch.

Threads can be manufactured in one of the below mentioned process.

• v  Thread cutting and thread milling are cutting methods that use a single-point tool and multi-point tool, respectively, to create threads on a blank or work piece.


• v  Thread rolling is a cold forming process that uses a die to deform metal and press it into the shape of threads. Figure 2 shows the mechanism that holds the dies.


• v  Thread tapping uses a drill-like tool to either cut or form threads on the ID of a previously drilled hole.


• v  Thread grinding uses an abrasive wheel to wear away material and create the thread. Thread grinding is the most precise method of producing threads

Threads may be cut using multiple methods. OD threads may be cut on a lathe or a mill. Both methods begin with a larger blank or work piece and use a cutting tool to remove material and shape the threads. In general, cutting threads is an efficient method, but it has its drawbacks. Cutting produces chips that can interfere with the threads, and the process can cause stress cracks in the metal.



A lathe uses a single-point tool, to cut the threads into the blank or work piece, which is held either between centers or in a chuck. The cutting tool is fed into the blank and moved sideways along the rotating piece. On the first pass, the tool is often used to scratch the surface so that the operator can inspect the scratch and verify the tool settings. Then the tool makes multiple passes, cutting deeper each time the tool travels the length of the cylinder.



Milling is another form of cutting. Thread milling is performed similarly to lathe cutting except that a multi-point tool is used. Also, when using a mill, it is usually the tool, not the work piece, that rotates. Milling can be performed more quickly than other methods, but it is generally not recommended for manufacturing smaller threads.

To continue ……………

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