The present invention relates to a new manufacturing method for gun barrel manufacturing. Gun barrels within the meaning of this invention include mortar cannon barrels, rifle barrels and also covers any shape which is used in the barrel manufacturing including air, naval, military, security & police forces and personal gun barrels including the sportive gun barrels.
Such gun barrels are usually hollow pipe like structures that comprise helical or straight groves and/or ribs (and/or different shaped profiles) that are usually formed on the inside surface of the structure.
Such barrels are usually manufactured by either a milling process in which the inside structure is formed by removing material from inside of a workpiece to form ribs or grooves. The other possible way is a forging process in order to produce the desired inside shape of the workpiece. Both methods do produce gun barrels in the desired shape, but the products produced still suffer from various disadvantages. One setback is that the precision and shape of the grooves and ribs produced as mentioned above is rather poor and not durable. This entails lack of performance on the finished produced involving such gun barrels.
An object of the present invention is to provide a superior method and an apparatus for producing rifled and/or inside shaped gun barrels, which reduced the setbacks set forth above.
A further object of the invention is to provide a forming method and an apparatus that are simple in application, inexpensive to manufacture, and highly effective in operation.
The above objects are solved by a method for producing gun barrels having a grooved or ribbed inner surface with straight or helical grooves or ribs, the method comprising the steps of:
The invention provides a method for producing gun barrels having a grooved or ribbed inner surface with straight or helical grooves or ribs. Rather than forging or milling the inside structure, the present invention involves flow forming technique in order to achieve the desired result.
According to the present invention, the method is carried out on a flow forming machine and comprises the following steps:
providing a metallic hollow cylindrical pre-form;
placing the pre-form on a core mandrel being part of a flow forming machine having a main machine axis, the core mandrel being not driven and being freely rotatable about the main axis and having a structured outer surface comprising ribs and/or grooves, the ribs and/or grooves extending straightly parallel to and/or helically around the main axis;
applying forming rollers comprised in a roller arrangement, to the outside surface of the pre-form so as to apply radial pressure on the pre-form such that its material begins to flow;
as the rollers apply force upon the pre-form, performing a relative motion between the pre-form and the rollers by either moving the pre-form in axial direction parallel to the main axis through the roller arrangement or by moving the roller arrangement alongside the pre-form.
The pre-form (starting material) may be closed or semi closed bottom shaped or can be open end on both sides. The pre-form can be an un-machined raw material (extruded pipe, welded or seamless tubes etc.) and/or a turned/machined part. Any type of flow formable material can be used as pre-form.
In one embodiment, the axial position of the rollers is kept fixed such that that the rollers lie in a predetermined position above the core mandrel between both axial ends of the core mandrel. Favorably, the pre-form is pushed in axial direction over the core mandrel towards the tail stock of the machine. The roller induced flow of material of the pre-form will fill the grooves and the spaces between ribs of the core mandrel and the mandrel will rotate in case the pressure is too high. As the pre-form is gradually pushed through the rollers applying pressure on the pre-form, the diameter of the pre-form is at the same time reduced and the inside contour is shaped. The barrel contours or shapes can vary anything from helical or straight groves or ribs, from rather shallow profiles to very steep or aggressive profiles.
As compared to conventional methods, to produce gun barrels, like hammer forging, button rifling and cut rifling (broaching, reaming, lapping) processes, the involvement of flow forming technique on a shaped core mandrel entails the following advantages:
Due to cold work hardening effect, the material properties of the produced workpiece can be improved. In longitudinal (axial) direction, the grains of the material can be refined and directed. Further, light weight barrel design is possible, as the ultimate tensile strength of the workpiece is improved. Further, usage of material can be reduced as machining processes for obtaining inside grooves are reduced or even eliminated (e. g. reaming, broaching, etc.). The method of the invention further provides for achieving finest geometrical tolerances for inside groves or ribs and produces minimized residual stress in the workpiece due to the continuous and smooth forming process. Other physical properties such as an excellent inner surface roughness, an improved straightness, improve cylindricity, and improved roundness tolerances are achieved as well.
A further advantage is a better material hardness variation along wall thickness which is also due to the continuous processing method of flow forming.
The core mandrel may also have a tapered shape, so that gun barrels with a slightly conical inner surface may be produced which promise less wear of material and thus a longer duration in use. In this case, the rollers and/or the core mandrel are designed to perform a limited relative motion with respect to one another. This relative motion may, however, be limited to a relative axial motion of the rollers between both axial ends of the core mandrel.
The apparatus for performing the method stipulated above, is a flow forming machine, which comprises:
a head stock, a tail stock opposing the head stock, a core mandrel extension rod rotatably supported in the head stock, and a driving means for driving said core mandrel extension rod to rotate about a main machine axis. The apparatus further comprises a core mandrel that is rotatably supported on a free end of the core mandrel extension rod. As such, the core mandrel is freely rotatable with respect to the core mandrel extension rod about the main machine axis of the flow forming machine. The apparatus further includes a set of forming rollers that are provided between the head stock and the tail stock. The rollers are radially displaceable toward the core mandrel in order to apply a radial force onto a cylindrical pre-form that is placed on the core mandrel. The core mandrel has a structured outer surface which comprises ribs and/or grooves. The ribs and/or grooves extend straightly parallel to and/or helically around the main machine axis. These ribs or grooves are a negative image on the actual inner contour to be shaped into the inside wall of the pre-form.
Favorably, the core mandrel extension rod and the rollers can be displaceable with respect to each other in a horizontal direction parallel to said main machine axis. Only a relative motion between both the rollers and the pre-form is required. This can be achieved by enabling the core mandrel extension rod and/or the rollers to be displaceable with respect to the head stock in a horizontal direction parallel to said main machine axis. During operation, the relative motion feeds the pre-form through the set of rollers which radially press onto the outside surface of the pre-form. This results in a shaping process that on the one hand reduces the wall thickness and lengthens the pre-form, on the other hand shapes the inner surface of the pre-form to receive the ribs or grooves.
Preferably, the core mandrel comprises a substantially cylindrical shape with said ribs and/or grooves formed on or in its outer surface. This is for forming cylindrical workpieces out of a cylindrical pre-form.
Alternatively, the core mandrel comprises a substantially conical shape with said ribs and/or grooves formed on or in its outer surface and tapering in the direction of the tail stock. This mandrel form is designed for forming cylindrical tapered workpieces out of a cylindrical pre-form.
According to another embodiment, the tailstock comprises a tail stock extension rod extending in the direction of the main machine axis and being rotatably supported by the tail stock to rotate about the main machine axis. In this configuration, the tailstock extension rod is held against the free end of the core mandrel. During the forming process the pre-form is elongated due to the reduction of its wall thickness and “grows” in length such that it is pushed over the core mandrel towards the tail stock onto the tailstock extension rod.
The tail stock extension rod is preferably displaceable in horizontal direction parallel to the main machine axis and extends coaxially with said core mandrel extension rod and said core mandrel. After forming, the finished workpiece can be unloaded from the machine by retracting the tail stock extension rod. This way, the workpiece is quickly and simply ejected from the forming mandrel after the part is formed.
After forming process the part is formed in accordance with the mandrel shape and forming roller path programmed on the machine control panel. The inside and outside contours can be vary in shape and/or different diameter zones can be created according to defined part program. Some of the possible geometries are illustrated in
The invention is described hereinafter with reference to the attached drawings depicted in
Drive 1 is designed to drives the core mandrel unit in axial direction X (positive and negative axial direction). The drive 1 may have position and/or force control capabilities. The movement of the drive 1 is independent from the axial movement of headstock 5. In some applications, the drive may be located onto the moveable parts of the headstock 5. In this case, the core mandrel 8 moves in accordance to the motion of headstock 5 to achieve the requested part geometries.
The drive can be isolated from the rotational movements of core mandrel extension rod 3 via a bearing 2. In some cases, the core mandrel axial drive 1 may rotate together or in accordance with the core mandrel extension rod 3. Preferably, the core mandrel extension rod 3 is a solid bar or hollow shaft which is located between the core mandrel 8 and the axial drive 1. The main function of core mandrel extension rod 3 is to keep and/or move the core mandrel 8 in the correct and pre-determined position during or prior to or after the forming process. Such action requires programming which can be made mechanically, e.g. via relay system, PLC or CNC or any other control device. According the requirements of the process, the extension rod 3 may either be guided in axial direction X and/or radial direction Y by the headstock 5—using a bearing 4—or alternatively by the tailstock 12. Depending on the requirements of the process, the extension rod 3 can be actuated in rotational direction via headstock 5, tailstock 12 and/or any other drive units.
The headstock 5, that comprises a spindle unit, is movable in axial direction X and drives the pre-form 10 through the forming rollers 90 comprised in the roller unit 9, over the core mandrel 8 during the forming process.
The pre-form 10 is driven in rotational direction about axis A via drive ring 6 and/or tapered part and/or any transmission device which is connected to headstock's 5 spindle. The headstock spindle 5 is actuated by common or separate actuation devices (e.g. electrical motor, hydro motor, etc.). Depending on the process requirements, the headstock 5 can be used to pull the pre-form parts 10 through the roller unit 9 (instead of pushing) to form the part in the aforementioned way. The headstock 5 and tailstock 12 units can interchange their functions.
As shown in
The core mandrel 8 forms the free end of the core mandrel extension rod and is freely rotatable via a bearing 7 and/or a guiding device and it will follow the axial position, i.e. the axial movement, of the core mandrel axial drive 1 system. Core mandrel 8 is not actively (e.g. by a controlled rotational drive) actuated in the rotational direction which means that the formed section of the material 10 flows under the radial pressure of the applied rollers 90 and the flow of material accordingly turns the mandrel in rotational direction. The core mandrel 8 is guided on the extension rod 3 via bearing 7 and/or another guiding system. The core mandrel 8 can be centered by using a centering device located on the machine frame, using a lunette, or involving the tailstock 12 and/or headstock 5 as a centering device. The core mandrel 8 may be non-cooled or internally and/or externally cooled using any cooling media.
As stated above, some of the possible geometries of the core mandrel 8 are illustrated in
The method according to the invention employs a roller unit 9 with one or more forming rollers 9 to form the barrel. The forming rollers 90 are actuated by axial and/or radial direction using a not shown machine control system. Each roller 90 can be actuated separately or all rollers 90 can be synchronized to move together using the control system. The forming rollers 90 can be free in rotational direction or be actuated by any drive system. The forming rollers 90 can vary in shape and dimensions and/or they can have an offset in axial direction X and/or radial direction Y. The forming position (axial and/or radial) of the rollers 90 can be changed during the forming process via the control system. Each forming roller 90 may have an angle referenced to machine central axis A. This angle can be adjusted automatically via the control system and/or manually. The roller 90 can be used for a stripping function and/or separate stripping devices can be employed.
The tailstock spindle unit 12 is movable in axial direction X and the main function of the tailstock 12 is to guide the pre-form 10 in axial direction X and/or radial direction and/or pull or push the pre-form to assist the process flow. The tailstock spindle 12 can be freely rotatable in rotational direction (about axis A) or can be actuated via separate actuation devices (electrical motor, hydro motor, etc.). The tailstock 12 and headstock 5 may interchange their functions.
The inventive method works as follows: a cylindrical, hollow metallic pre-form 10 is placed over the mandrel 8 and the extension rod 3 to abut against the drive ring 6,
As the rollers 90 apply pressure they are turned as indicated by the arrows in
Number | Date | Country | Kind |
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2016/03523 | Mar 2016 | TR | national |
This application claims the benefit of and is the US National Phase of International Application No. PCT/EP2017/051773 having an International Filing Date of 27 Jan. 2017, which claims the benefit of Turkish Patent Application No. 2016/03523 having a filing date of 17 Mar. 2016.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/051773 | 1/27/2017 | WO | 00 |