In recent years, there has been a push from the medical industry to use bone screw applications with hex shapes, Torx or Hex lobular and square and spline drives. In doing so, materials such as titanium, cobalt and high-temperature alloys have made the job of putting a shape in the head of a screw much more difficult.
Rotary broaching, also known as wobble broaching, has been one method used to obtain these various shapes. Well known and used for years on automatic lathes, rotary broaching has become the method of choice on Swiss-type machines, CNC lathes and machining centers because it eliminates a secondary operation.
The basic principle of rotary broaching is relatively simple. Internal and external polygonal profiles are single-point shaped rather than form punched. The operation is performed in only a few seconds while the spindle is rotating. Rotary broach manufacturer PCM Willen SA (Villeneuve, Switzerland) reports that the cutting action requires 80 percent less force than form punching when the optimum feed rate is used. The reduced stress increases tool life and lowers machine maintenance cost over time.
On a machining center, the broach holder revolves in the spindle while the tool and part are stationary. This is opposite of how one is positioned on a lathe where the part rotates synchronously with the tool while the holder is held in an endworking position. The operation takes only seconds and can eliminate a secondary operation so the part can be produced completely in one setup.
The broaching holder serves two functions: It holds the broach tool in a free spinning bearing and places it at a 1-degree angle relative to the centerline of the workpiece. The face of the broach tool is the apex of the 1 degree and is located on the same centerline as the workpiece. A 1 1/2-degree clearance angle is built into the tool. As the tool comes into contact with the spinning part, it begins to rotate synchronously like a gear because of friction. As the tool is thrust into the pre-drilled hole, the wobble effect causes the leading edge to rotate in and out of the cut like a cam.
As the tool advances forward in a wobbling motion, each tooth cuts the same groove with a scalloping effect as it rotates in and out of the leading point position. This is similar to a wobbling coin, only one point is touching at any given time, greatly reducing the amount of force needed to form the shape.
The following information includes tips and tutorials on how to broach a hole to quality standards.
Preparing to broach a hole – The hole should first be prepared with a 60-degree to 90-degree chamfer slightly bigger than the largest dimension of the broach tool. This ensures easy starting of the broach by guiding the tool.
Drilling the hole – For internal broaching, the hole should be drilled approximately 1 percent bigger than the diameter across the flats of a hex shape. This percentage can be reduced when free cutting material and increased as machinability decreases. For mild steel, the following tolerances are recommended:
0.059 - 0.118 = 0.001 - 0.002
0.118 - 0.236 = 0.0015 - 0.0035
0.236 - 0.394 = 0.0025 - 0.005
0.394 - 0.630 = 0.004 - 0.008
> 0.630 = 0.006 - 0.012
Drill the hole as deep as possible to leave room for chip accumulation. A depth of 1.3 to 1.5 times the length of the profile is recommended. If the chips need to be removed, re-drill the hole with a slightly smaller drill size.
Drill radius not allowed – Many medical and aerospace applications do not allow for a drill radius along the broached walls of the part. When exact concentricity is required, co-bore, drill and pre-bore the hole, which will keep the broach concentric when it enters the hole.
As the broach plunges into a tight fitting hole, there is no room for air or coolant to escape. The hydraulic pressure being generated is enough force that something must give. Many times, the part or tool will push back, which may cause tool or machine damage. In this case, use of a pressure relief vent in the broach is recommended, allowing oil and air to escape.
Recommended speed – The basic principle of the 1-degree offset allows high speed applications from 1,500 rpm up to 3,000 rpm. Surface footage has little affect on the cutting action or the tool life. The cutting edges of the broach tend to dig into the part face as the tool comes into contact with the rotating material. At higher speeds, this dig mark will become more pronounced and tool life will suffer. For best results, start the broach operation at a slow rotation, and then increase the speed when it is in full contact. Reversing the spindle rotation halfway into the part can reduce spiraling.
Feed rate – The feed choice mainly depends on the material characteristics. In mild steel, 0.0012 to 0.0024 per revolution is recommended. If the machine thrust force is sufficient, the feed can be doubled (even tripled) as machinability increases. In most cases, the maximum feed rate should not exceed 0.03 times the profile diameter. A slower feed rate will produce an improved finish with finer lines along the sidewalls of the broached hole. By increasing the feed rate, the cutting cycle will be faster, but the broaching lines will be more pronounced, leaving a coarse finish.
Coolant – Water-soluble coolant or cutting oil are both sufficient for rotary broaching. The increased size of the pre-drilled hole usually provides ample space for coolant to leak out as the broach tool plunges in. In a tight-fitting hole, a pressure relief vent should be added to the broaching tool.
Centering the broach – To obtain a quality broached hole and to optimize tool life, the tool should be on center with the workpiece within 0.0008 inch or less. Poor centering will result in the shape being eccentric with the bore, as well as spiraling, increased dig marks at the start, oversized holes and reduced tool life.
Centering the broach tool with the workpiece can be achieved in or out of the machine. However, the most accurate way to indicate the tool is to do so on the machine while the tool is in the station that will be used for broaching.
For machines like turret lathes that cannot place the tool accurately with the spindle center line, an adjustable broaching head should be used. With an adjustable head, a gage pin that is the same length as the broach, is inserted into the head and the tip is indicated to find the center.
Adjusting centering off-line – (See Fig. 1) Set the indicator tip (5) on the gage pin (4) at the correct "L." Rotate the holder on its shank (2) in the preset fixture (1) to obtain a maximum TIR of 0.0008 inches. (Notice the oscillation of the gage pin as it rotates with the holder.)
Adjust the position using the four adjusting screws. Upon completion, clamp the head tight with the clamping screws. Check again after clamping.
Adjusting center on the machine – (See Fig. 2) This offers the advantage to correct misalignment between the machine spindle and the turret bore. With the gage pin (4) set to the proper "L," set the broach head in the turret station (1) to be used for broaching. Set the indicator (5) on to the spindle chuck with a magnetic base. Place the indicator tip on to the end of the gage pin. Rotate the chuck so the indicator sweeps the diameter of the pin, and adjust accordingly using the adjusting screws.
Medical Parts Maker Applies Rotary Broach
One company that's currently using rotary broaching is Astro Medical Devices (Mentor, Ohio), which specializes in the production of medical implants and ultra-precision machining. Using a bank of Citizen CNC Swiss machines, the company runs broaching jobs 24 hours a day, 7 days a week.
Swiss Machinist Brian Baxter and the lead Swiss and EDM supervisor at Astro Medical, Jerry Pataki, are two of the company's key people in charge of maintaining a smooth production environment. Searching for ways to increase productivity, they tried a PCM rotary broaching holder made by PCM Willen SA (Villeneuve, Switzerland) and distributed by Genevieve Swiss Industries (Westfield, Massachusetts). Designed specifically for Swiss machines and other high-precision machines, the non-adjustable broaching holder is designed to virtually eliminate setup time.
Since the introduction of the PCM/Genevieve broach head, Astro Medical has seen almost a 78 percent reduction in time spent setting broach tools. When asked what the operators like best about these broach holders, Mr. Baxter states, "We love the fact that we don't have to center these heads. They don't take any more time to set up than drills." These holders are already on center and take less than a few minutes to set up.
The company broaches various materials including titanium and medical grade stainless for bone screws. Continuous broaching of these high-strength materials is hard on the bearings used in broaching heads and can cause short bearing life. Maintaining a high quality level requires the equipment to be kept in tip-top shape.
Another benefit Mr. Pataki has discovered is the lower maintenance cost. The company has had its first 2100 Series holder in service for almost 2 years. "Our old broaching holders need to be rebuilt often to hold the tolerances we require. The PCM/Genevieve head just keeps going," Mr. Pataki says.
The design of this rotary broach holder allows the tighter tolerance control required for medical and aerospace industries. The compact design combined with a medium-duty bearing provides a more rigid setup that is able to withstand the increased pressure generated when broaching titanium and other high-strength alloys.
These rotary broach holders are intended for machines that are more accurately centered, such as Swiss-type screw machines and gang lathes. These holders are on center and take less than 3 minutes to set up. The broach head places a qualified tool on center with the part, taking no more time to set up than a standard ID tool. The design allows tighter tolerances to be held, while simplifying set up.
According to PCM Willen, almost all free-cutting materials can be successfully broached up to 850 N/mm2 tensile strength without greatly reducing tool life. Materials such as heat-treated steels and non-free-cutting stainless steel will reduce tool life depending on hardness.
The 2160 Series broach holders have also been critical to the company's manufacturing process. Designed for Swiss-type machines, this broach holder has a maximum diameter of slightly larger than an inch and a head length of slightly smaller than 2 1/2 inches to the tip of the broach. It easily fits into machines with the tightest tooling layouts and comes with an extended tool shank allowing it to be cut shorter for machines with limited space. The proprietary bearing is able to withstand more than 2,000 pounds of thrust. This is an ideal condition for tough materials such as titanium jobs that Astro Medical runs. "We like the 2160 because it is customizable," Mr. Baxter says. "We can use it for subspindle work, or use it in any ID turret station and not worry about being off center."
Not only is proper centering required for accurate broaching, but it helps to have a reliable tool to start with. The company purchases the PCM broaches from Genevieve Swiss because they are qualified broaches. Many of the sizes Astro Medical uses must be held within 0.0004 inch on the diameter. Genevieve Swiss carries many of these sizes in stock. "We've been getting great tool life, generally about 1,000 bone screws per broach tool. We also make small-set screws with a T-15 Hex lobe form and typically get about 1,500 parts per tool," Mr. Baxter explains. "Change-over is also easy since all broaches are qualified. When a tool wears out, we can change it out and start making parts again within 30 seconds." he added. The PCM broaches are made from high cobalt European tool steel. Many of the tools supplied by Genevieve Swiss also have a pressure vent that relieves oil and air as the tool enters a tight tolerance hole.