JP6045434B2 - Hot forging method - Google Patents

Description

  The present invention relates to a hot forging method in which forging is performed while imparting lubricity to a die and a forged product, for example, when forging a titanium forged product using a die.

Generally, titanium alloys such as pure titanium and Ti-6Al-4V have excellent mechanical properties and corrosion resistance, and are therefore used in engine members for transportation equipment such as aircraft and vehicles, and structural members such as chassis.
When forging the above-described forged product using such pure titanium or titanium alloy, a hot upset forging method using a mold is generally used. In the upset forging method, a heated work material is charged into a mold formed in advance to simulate a product shape, and the work material is stretched to a shape along the mold while maintaining a high temperature state. Forging while deforming. If the upset forging method is used, a metal flow that conforms to the product shape can be obtained in the deformation during forging, so that a forged product that is more tenacious and superior in impact fracture resistance than other processing methods can be obtained. In this upset forging method, a lubricant that provides lubricity between the mold and the workpiece is used in order to achieve the desired deformation and metal flow of the workpiece. As an upsetting forging method using a lubricant, there are those shown in Patent Document 1 and Patent Document 2.

  These Patent Document 1 and Patent Document 2 disclose a method of forging by covering a workpiece with a lubricant containing a solid lubricant component of graphite or boron nitride and a vitreous component in advance.

Japanese Patent Laid-Open No. 55-19494 Japanese Patent Laid-Open No. 3-109491

However, Patent Documents 1 and 2 disclose that a workpiece is coated with a lubricant before forging, but it is difficult to ensure lubricity during forging even if these methods are used. However, there is a need for a new technology that can ensure sufficient lubricity.
This invention is made | formed in view of the above-mentioned problem, and provides the hot forging method which can perform upset forging, ensuring favorable lubricity between a metal mold | die and a workpiece. With the goal.

In order to achieve the above-described object, the present invention takes the following technical means.
In the hot forging method according to the present invention, after applying a liquid lubricant to a work material, the work material applied with the liquid lubricant is heated, and the hot work material is upset and forged. In the method, when the liquid lubricant is applied to the workpiece, the liquid lubrication is performed so that a lubricating film formed on the surface of the workpiece having a shot skin does not exceed 0.4 mm and does not exceed 0.5 mm. When the work material coated with the liquid lubricant is heated, the holding time (hr) for holding the work material at a temperature of 600 ° C. or higher and “forging temperature −200 ° C.” or higher is “ More than the time required by “5 × Lubricating film thickness (mm)”.

  According to the hot forging method of the present invention, upsetting forging can be performed while ensuring good lubricity between the mold and the workpiece.

It is a schematic diagram for demonstrating the hot forging method of this invention.

Hereinafter, the hot forging method of the present invention will be described in detail with reference to the drawings.
The hot forging method (upsetting forging method) of the present invention is performed using an upsetting forging apparatus as shown in FIG.
As shown in FIGS. 1 (e) to 1 (g), the upset forging device 1 inserts a heated workpiece (hereinafter referred to as wasteland) 2 into a mold 3 and molds the mold. The forged product W having a desired shape is formed by deforming the wasteland in a hot state along the shape 3. Specifically, the upset forging device 1 is configured such that the mold 3 for forming the forged product W can be divided into two vertically, a lower mold 4 on which the wasteland 2 is placed, And an upper mold 5 for reducing the waste land placed on the lower mold 4 from above.

The wasteland 2 is made of pure titanium or titanium alloy such as Ti-6Al-4V, and has a substantially cylindrical shape that is elongated in the vertical direction. The upper and lower edges are chamfered diagonally. Is formed.
The lower mold 4 has a cylindrical mold upper part 6 that can accommodate the wasteland 2 therein, and a mold lower part 7 that is provided below the mold upper part 6 and supports the wasteland 2 from below. . A hole 8 having an inner diameter larger than the outer diameter of the wasteland 4 is formed in the center of the mold upper portion 6 so as to penetrate in the vertical direction, and the wasteland 2 is inserted into the hole 8 from above. It can be inserted downward.

  A vertical hole-like through hole 9 having a smaller diameter than the rough ground 2 (inner diameter of the hole 8) is formed on the lower side of the hole 8 on the center side of the mold lower part 7. Specifically, a through hole 9 is formed in the central portion of the mold lower portion 7, with the inner diameter gradually decreasing as it goes downward following the hole 8, and the inner diameter is constant from the midway portion. The wasteland 2 can be placed on the inner inclined surface 9 a that forms the through hole 9.

  Further, a mold support mechanism (not shown) is provided below the mold lower part 7 so that the lower mold 4 can be supported on the floor surface or the like by the mold support mechanism. Further, on the lower side of the lower die 4, a knockout bar 10 for discharging the forged product W after forging and a cylinder mechanism (not shown) for moving the knockout bar 10 in the vertical direction are provided. The knockout bar 10 is arranged at a position corresponding to the through-hole 9 of the lower mold 4 so as to be movable in the vertical direction. The knockout bar 10 is moved upward by a cylinder mechanism so that the forged waste 2 (forged product W) ), The forged product W can be peeled off from the die.

The upper mold 5 is located above the lower mold 4 and is approached and separated from the upper side with respect to the rough ground 2 placed on the lower mold 4. By lowering the upper mold 5, It is possible to reduce the wasteland 2 by crushing it from above. A punch 11 for reducing the wasteland 2 is formed at the center of the upper mold 5.
The punch 11 has an outer diameter that is slightly smaller than the opening diameter of the hole 8 in the mold upper part 6, and when the upper mold 5 is lowered until it abuts the lower mold 4, the hole in the mold upper part 6 The upper part of the wasteland 2 can be crushed from above.

Next, forging by the above-described upset forging apparatus will be described in detail.
In the upsetting forging method of the present invention, first, before forging the wasteland 2 by the upsetting forging apparatus 1, the surface of the wasteland 2 is pretreated (FIGS. 1A to 1D). The wasteland 2 is forged after completion of the pretreatment (FIG. 1 (e) to FIG. 1 (g)).
Specifically, as shown in FIG. 1A, in the pretreatment, first, the surface of the wasteland before forging is degreased in a degreasing step. Thereafter, as shown in FIG. 1 (b), the liquid lubricant 12 is applied (pre-coated) to the rough soil 2 after degreasing in the pre-coating process, and after the pre-coating in the heating process as shown in FIG. 1 (c). The wasteland 2 is charged into a heating furnace or the like to heat the entire wasteland. When the heating of the wasteland is completed, as shown in FIG. 1 (d), after the wasteland 2 heated in the takeout step is taken out, upset forging is performed.

In the upsetting forging method of the present invention, the pre-coating process and the heating process are defined in particular so that the liquid lubricant 12 applied to the surface of the wasteland 2 acts sufficiently during forging.
Next, the precoat process and the heating process will be described in detail.
The liquid lubricant 12 used in the precoating process is glass (referred to as a liquid glass lubricant) containing SiO ₂ , B ₂ O ₃ or the like, and mainly contains glass particles of several μm to several tens of μm. .

In the pre-coating process, the degreased wasteland 2 is preheated to 80 to 100 ° C. in advance, and the liquid glass lubricant 12 is applied to the entire surface of the wasteland 2 after preheating.
When the liquid glass lubricant 12 is applied to the surface of the wasteland 2, moisture and the like contained in the liquid glass lubricant 12 evaporate. ) 12a is formed. In other words, after the liquid glass lubricant 12 is applied to the surface of the rough ground 2 and the applied portion is dried, a glass lubricating film 12a is formed. As described above, since the wasteland 2 is preheated in advance before the liquid glass lubricant 12 is applied to the wasteland 2, the application portion is dried by the heat after preheating after the liquid glass lubricant 12 is applied. Even if it does not provide etc., it will dry naturally. In addition, after apply | coating the liquid glass lubricant 12 to the rough ground 2, you may make it dry forcedly using a drying apparatus.

In this pre-coating step, it is preferable to make the glass lubricant film 12a after drying as thick as possible. In order to increase the thickness of the glass lubricant film 12a, for example, application of the liquid glass lubricant 12 and drying are repeated. It is desirable to do.
For example, the application and drying of the liquid glass lubricant 12 are repeatedly performed so that the thickness of the glass lubricant film 12a formed on the surface of the wasteland 2 after drying is as close to 0.5 mm as possible. However, if the thickness of the glass lubricating coating 12a is too large, the glass lubricating coating 12a is likely to be peeled off or bubbles are generated in the heating step and subsequent steps, and as a result, the lubricity may be reduced. . Therefore, in the present invention, in the precoating process, the liquid glass lubricant 12 is applied so that the glass lubricant film 12a does not exceed 0.5 mm. Preferably, the glass lubricating coating 12a does not exceed 0.45 mm.

As described above, when the glass lubricant film 12a is formed on the surface of the wasteland 2 in the precoat process, the wasteland 2 is moved to a heating furnace or the like, and the wasteland 2 is heated to a temperature of 600 ° C. or higher in the heating process. When the wasteland 2 is heated to 600 ° C. or more, most of organic components such as a binder contained in the glass lubricating film 12a are promoted to volatilize.
If the heating time of the wasteland 2 is not sufficiently ensured in the heating step, the glass lubricating coating 12a having excellent lubricity and high uniformity cannot be formed during forging. Therefore, in the heating process, the holding time of the wasteland 2 (time for holding at 600 ° C. or higher) is defined based on the glass lubricating film 12a formed in the precoating process. Specifically, in the heating step, the holding time (hr) for holding the wasteland 2 at a temperature of 600 ° C. or higher is set to be equal to or longer than the time required by “5 × thickness of glass lubricating coating (mm)”. For example, when the thickness of the glass lubricating coating at the time of drying is 0.4 mm, the wasteland 2 is held at 600 ° C. or higher for 2 hours or longer.

  In the heating step, the temperature for holding the wasteland 2 is preferably the temperature during forging (forging temperature), but may be at least “forging temperature−200 ° C.” or more based on the forging temperature. When the liquid glass lubricant 12 suitable for the viscosity characteristics at the forging temperature is used, the glassy component contained in the liquid glass lubricant 12 is softened (melted) if approximately “forging temperature−200 ° C.” or higher. Thus, a highly uniform glass lubricating coating 12a can be formed. More preferably, the holding time (hr) for holding the wasteland 2 at a temperature of 600 ° C. or higher is set to be “10 × thickness of glass lubricating coating (mm)” or more.

  As described above, in the pre-coating step, after the liquid glass lubricant 12 is applied to the preheated wasteland 2, it is dried to remove moisture, etc. 0.45 mm or less) is formed. Furthermore, in the heating step, the holding time (hr) for holding the wasteland 2 at 600 ° C. or higher is set to be equal to or longer than the value obtained by “5 × glass lubricating film thickness (mm)”.

  By passing through such a pre-coating process and a heating process, the coating failure (peeling, bubble generation, etc.) of the glass lubricating film 12a after the heating of the wasteland 2 can be suppressed, and a trace amount contained in the glass lubricating film 12a can be suppressed. By promoting the volatilization of organic components such as moisture, air and binder, a highly uniform glass lubricating coating 12a having excellent lubricity during forging can be obtained. In addition, the surface of the rough ground 2 to which the glass lubricating coating 12a is applied is, for example, like a shot skin, it is easier to form a coating that does not peel easily and has a low roughness when the surface state is moderately large. This is desirable because the coating failure can be suppressed more than the surface state.

Next, forging by the upsetting forging apparatus will be described in detail.
After the completion of the pretreatment, the wasteland 2 on which the glass lubricating coating 12a is formed is charged into the upsetting forging device 1. That is, as shown in FIG. 1E, the waste land 2 is inserted between the upper mold 5 and the lower mold 4, and the upper mold 5 is pushed down until the punch 11 contacts the upper surface of the waste land. Thereafter, as shown in FIG. 1 (f), the wasteland 2 is reduced. That is, after the upper die 5 is pushed down until the upset forging punch 11 comes into contact with the wasteland 2 and the upper die 5 is further moved downward, the punch 11 of the upper die 5 is moved into the hole 8. The wasteland 2 housed in the mold is crushed downward, and the crushed and deformed material spreads to fill the inside of the mold upper part 6. Even if the inside of the mold upper portion 6 (hole portion 8) is filled, a surplus material flows into the through hole 9. As a result, the material constituting the wasteland 2 spreads over both the hole 8 and the through-hole 9, and a cylindrical body having a small diameter is coaxially overlapped below a cylindrical body having a large diameter. A forged product W having a shape (substantially bolt shape) is formed.

As shown in FIG. 1G, when the forging described above is completed, the knockout bar 10 is moved upward, and the forged product W is pushed up by the knockout bar 10. Then, the forged product W fixed to the lower mold part 7 is peeled off from the lower mold part 7, and the forged product W can be taken out from the mold 3.
As described above, according to the present invention, the glass lubricating film 12a formed on the surface of the wasteland 2 in the precoating process is made appropriate, and the wasteland 2 is held at a predetermined temperature or higher (for example, 600 ° C or higher) by the heating process. By making the time appropriate, good lubricity can be ensured between the mold 3 and the wasteland 2. That is, poor coating (peeling, generation of bubbles, etc.) of the wasteland 2 due to the coating agent (liquid lubricant) after heating (before forging) can be suppressed. Further, the surface of the wasteland 2 can be coated with high uniformity with excellent lubricity.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. In particular, in the embodiment disclosed this time, matters that are not explicitly disclosed, for example, operating conditions and operating conditions, various parameters, dimensions, weights, volumes, and the like of a component deviate from a range that a person skilled in the art normally performs. Instead, values that can be easily assumed by those skilled in the art are employed.

  In the above-described embodiment, the glass lubricating film 12a is formed on the surface of the wasteland 2, but in addition to this, after the heat treatment (before forging), by applying a powdered glass lubricant to the surface of the wasteland 2, the wasteland 2 is formed. The surface coating may be further strengthened. Further, when placing the wasteland 2 on the upsetting forging apparatus 1 (lower mold 4), the forged wasteland 2 is separated between the wasteland 2 and the lower mold 4 so that the forged wasteland 2 is easily separated from the lower mold 4. Forging may be performed after providing the mold.

1 Upset forging device 2 Work material (waste ground)
3 Mold 4 Lower mold 5 Upper mold 6 Mold upper part 7 Mold lower part 8 Hole part 9 Through hole 9a Inner inclined surface 10 Knockout stick 11 Punch 12 Liquid lubricant (liquid glass lubricant)
12a Lubrication coating (glass lubrication coating)
W forged products

Claims (1)

In a hot forging method in which after applying a liquid lubricant to a workpiece, heating the workpiece coated with the liquid lubricant, upsetting and forging the heated workpiece,
When applying the liquid lubricant to the workpiece, apply the liquid lubricant so that the lubricating coating formed on the surface of the workpiece having a shot skin does not exceed 0.4 mm and 0.5 mm. And
When heating the workpiece coated with the liquid lubricant, the holding time (hr) for holding the workpiece at a temperature of 600 ° C. or higher and “forging temperature −200 ° C.” or higher is set to “5 × lubricating coating. A hot forging method characterized in that the time is equal to or longer than the time required by “thickness (mm)”.