JP2014140901A - Extrusion die - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide extrusion dies in which a mandrel ring is externally fitted onto an arbor, and the mandrel ring is stably fixed and which is easily maintained and keeps the die strength for a long term.SOLUTION: A mandrel (30) for forming an inner surface of an extruded material has an arbor (32) and a mandrel ring (35) externally fitted onto the arbor. The mandrel ring (35) is configured in such a manner that a hard alkali-proof film (39b) is formed at least on an outer circumferential surface of a base material (39a) made of the material with a thermal expansion coefficient smaller than that of the arbor (32). An outer circumferential surface (32a) of the arbor (32) and an inner circumferential surface (35a) of the mandrel ring (35) while the mandrel ring (35) is externally fitted onto the arbor (32) is set in such manner that a gap exists between the outer circumferential surface (32a) and the inner circumferential surface (35a) at an ordinary temperature and that the gap does not exist and both of the surfaces come in contact with each other in at least a portion in the axial direction of the mandrel (30) at a die temperature during extrusion.

Description

  The present invention relates to an extrusion die used for extrusion of a hollow material.

  In the description of the present specification and claims, the direction in which the extruded material and the extruded material travel is referred to as downstream or downstream side, and the reverse direction is referred to as upstream or upstream side.

  In an extrusion die, a cemented carbide material such as cemented carbide or ceramic is used for a part of the die including the bearing unit in order to give wear resistance to the bearing unit (see Patent Documents 1 to 3).

  Patent Document 1 describes a die in which a ring-shaped die made of a super hard material is shrink-fitted in a recess of a die case made of tool steel. In Patent Document 2, a mandrel mandrel is formed of tool steel, a mandrel ring made of a super hard material is fitted on the mandrel, and a retaining nut is attached to the tip of the mandrel to fix the mandrel ring to the mandrel. The male type of the porthole die configured as described above is described. In addition, the die described in Patent Document 3 is obtained by shrink-fitting a mandrel ring with a sleeve softer than the mandrel interposed between the mandrel and the mandrel ring.

JP-A-6-15348 JP 2003-181525 A Japanese Examined Patent Publication No. 4-69009

  However, the type of die for shrink-fitting a super hard material has a problem that it takes time and effort for the preparation process and maintenance of extrusion.

  In addition, cemented carbide has a characteristic that its thermal expansion coefficient is smaller than that of tool steel, and it is weaker in tensile force than tool steel. For this reason, when a mandrel ring made of a super hard material is externally fitted to a mandrel made of tool steel, the mandrel expands during hot extrusion and may be damaged if the clamping force against the mandrel ring is too strong. On the other hand, if the tightening force is too weak, the mandrel ring is not firmly fixed, and there is a possibility that the piecing portion of the extruded material may be wavy or uneven. Further, the mandrel ring may come off the mandrel due to the flow of the extruded material.

  Furthermore, if the die after extrusion is washed with a strong alkaline solution such as caustic soda to remove the extruded material clogged inside, Co contained in the cemented carbide dissolves and the strength of the mandrel ring is reduced. As a result, the die life is reduced.

  In view of the above-described technical background, the present invention provides an extrusion die for externally fitting a mandrel ring to a mandrel, in which the mandrel ring can be stably fixed, maintenance can be performed easily, and die strength can be maintained over a long period of time. With the goal.

  That is, this invention has the structure as described in [1]-[7].

[1] A mandrel for molding the inner surface of the extruded material has a mandrel and a mandrel ring fitted on the mandrel.
The mandrel ring is formed by forming a hard alkali-resistant coating on at least the outer peripheral surface of a base material made of a material having a smaller coefficient of thermal expansion than the mandrel,
The outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are in a state where the mandrel ring is externally fitted to the mandrel, there is a gap between them at room temperature, and at the die temperature during extrusion, at least in the axial direction of the mandrel An extrusion die characterized in that it is set so that there is no gap and the two come into contact with each other.

  [2] The extrusion die according to claim 1, wherein the mandrel ring is formed with an alkali resistant coating only on an outer peripheral surface and an inner peripheral surface of a base material.

[3] When the clearance (X _T2 ) between the mandrel and the mandrel ring at the die temperature (T ₂ ) at the time of extrusion is expressed by the following formula at the portion where the gap at the normal temperature (T ₁ ) is minimized, The outer diameter (A _T1 ) of the mandrel at (T ₁ ) and the inner diameter (B _T1 ) of the mandrel ring are set so that the tightening allowance (X _T2 ) is 0 to 0.3% or The extrusion die according to 2.
X _T2 = {[A _T1 × (T ₂ −T ₁ ) × α ₁ + A _T1 ] / [B _T1 × (T ₂ −T ₁ ) × α ₂ + B _T1 ] −1} × 100
Where α ₁ : coefficient of thermal expansion of the material constituting the mandrel
α ₂ : coefficient of thermal expansion of the material constituting the base material of the mandrel ring (α ₁ > α ₂ )
T ₁ : normal temperature
T ₂ : Die temperature during extrusion (> T ₁ )
A _T1 : Outer diameter of the mandrel at normal temperature (T ₁ )
B _T1 : Inner diameter of mandrel ring at normal temperature (T ₁ ) (> A _T1 )
[4] At the die temperature (T ₂ ) at the time of extrusion, the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are in contact with each other because there is no gap in at least a part of the mandrel in the axial direction. The extrusion die according to any one of the preceding items 1 to 3, wherein the extrusion die is set to be an inclined surface that is inclined outward toward the downstream side of extrusion with respect to the axis of the mandrel.

[5] In a state where the mandrel ring is externally fitted to the mandrel, there is a gap between the two at normal temperature (T ₁ ), which becomes narrower on the downstream side of the extrusion and wider on the upstream side, and the die temperature (T _2. The extrusion die according to any one of the preceding items 1 to 3, wherein the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are formed so that the gap is eliminated at least on the downstream side in ₂ ).

  [6] The extrusion die according to any one of [1] to [5], wherein the mandrel protrudes from a base portion of the die, and the mandrel is detachably attached to the base portion.

  [7] Using the extrusion die described in any one of 1 to 6 above, extrusion is performed at a temperature at which there is no gap in at least part of the axial direction between the mandrel and the mandrel ring, and alkali cleaning is performed in the die maintenance after extrusion. Extrusion method characterized by performing.

  According to the invention described in [1] above, in the mandrel having the mandrel ring fitted on the mandrel, when the die reaches the temperature at the time of extrusion, the difference between the two due to the difference in thermal expansion coefficient between the mandrel and the base material of the mandrel ring. The mandrel ring is fastened to the mandrel by being tightened by the radial force that the mandrel tries to expand. Thus, when extrusion is performed with the mandrel ring fixed to the mandrel, uneven thickness of the extruded material is suppressed, and a high-quality extruded material can be produced. In addition, since there is a gap between the mandrel ring and the mandrel ring at room temperature, the mandrel ring can be easily attached to and detached from the mandrel, and maintenance such as replacement of the mandrel ring can be easily performed.

  In addition, a hard alkali-resistant coating is formed on at least the outer peripheral surface of the mandrel ring base material to protect the base material, so that during extrusion, the base material is not worn by the extruded material, and die maintenance is performed after extrusion. In this case, it is possible to prevent the components from being dissolved on the surface of the base material by alkali cleaning, thereby preventing the base material from being worn. Furthermore, the abrasion resistance of the alkali-resistant coating prevents the coating itself from being worn by extrusion, and the dissolution preventing effect can be maintained for a long period. In addition, since it is possible to re-form the alkali-resistant coating against the mandrel ring removed from the mandrel, the strength of the mandrel ring can be increased by protecting the base material with the alkali-resistant coating and re-forming the alkali-resistant coating. The life span can be extended by maintaining the period.

According to the invention described in [2] above, the alkali resistant coating is formed on the inner peripheral surface in addition to the outer peripheral surface of the mandrel ring to which the extruded material adheres. For this reason, even if the cleaning liquid enters the gap (S ₁ ) generated between the mandrel ring and the mandrel in the die cleaning after the extrusion, the inner peripheral surface of the base material is protected by the alkali-resistant coating film. Melting of the inner peripheral surface is prevented, and a change in the inner diameter of the mandrel ring can be prevented. Thereby, since the inner diameter of the mandrel ring is maintained, the fixing stability in the radial direction of the mandrel ring can be maintained. Furthermore, the surface treatment cost can be reduced because the alkali resistant coating is not formed on the end face of the mandrel ring.

According to the invention described in [3] above, since the tightening margin (X _T2 ) between the mandrel ring and the mandrel ring at the die temperature at the time of extrusion is set in an appropriate range, a stable fixed state is obtained, In addition, breakage of the mandrel ring can be avoided.

  According to the invention described in [4] above, the contact surface between the mandrel and the mandrel ring at the die temperature during extrusion is an inclined surface that inclines outward toward the downstream side of the extrusion with respect to the axis of the mandrel. Therefore, even if the flow of the extruded material tries to push the mandrel ring to the downstream side, the outward inclined surface acts in a direction to prevent the movement, thereby providing a retaining effect. Therefore, the movement of the mandrel ring is suppressed and high fixing stability is obtained.

  According to the invention described in [5] above, since the gap between the mandrel ring and the mandrel ring at normal temperature is narrow on the downstream side and wide on the upstream side, the tightening force at high temperature becomes stronger on the downstream side and becomes upstream. It becomes weak. Due to such a difference in stress distribution, a force opposite to the extrusion direction acts. This reverse force acts against the force by which the extruded material pushes the mandrel ring downstream, so that the downstream movement of the mandrel ring during extrusion is suppressed, and the positional stability of the mandrel ring is improved.

  According to the invention described in [6] above, since the mandrel mandrel is detachable from the base portion of the die, the mandrel can be replaced, and maintenance can be performed more easily. In addition, since the mandrel ring can be fitted from the upstream side of the mandrel, when one or both of the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are inclined with respect to the axis, the degree of freedom in designing the taper angle thereof. Is higher than a mandrel with a mandrel integrated with the base.

  According to the invention described in [7] above, since extrusion is performed in a state where the mandrel ring is fixed to the mandrel, a high-quality extruded material in which uneven thickness is suppressed can be manufactured. Moreover, since the entire surface of the mandrel ring substrate is protected by a hard alkali-resistant coating, wear of the substrate due to the extruded material is prevented during extrusion, and in the die maintenance after extrusion, the base by alkali cleaning is prevented. Since dissolution of the contained components on the surface of the material is prevented and wear of the substrate is prevented, a high-quality extruded material can be produced over a long period of time.

It is a disassembled perspective view which shows the porthole die provided with the male type | mold which is one Embodiment of this invention. It is sectional drawing which shows the assembly | attachment state of the porthole die of FIG. It is sectional drawing which shows the decomposition | disassembly state of the mandrel of 1st Embodiment. It is sectional drawing which shows the other example of formation of the alkali-proof film in the mandrel ring of FIG. It is sectional drawing which shows the other example of formation of the alkali-proof film in the mandrel ring of FIG. It is sectional drawing which shows the other example of formation of the alkali-proof film in the mandrel ring of FIG. It is sectional drawing which shows the other example of formation of the alkali-resistant film in the mandreling of FIG. 4A. It is sectional drawing which shows the state at the time of normal temperature of the mandrel of 1st Embodiment. It is sectional drawing which shows the state at the time of the die temperature at the time of extrusion of the mandrel of 1st Embodiment. It is sectional drawing which shows the decomposition | disassembly state of the mandrel of 2nd Embodiment. It is sectional drawing which shows the state at the time of normal temperature of the mandrel of 2nd Embodiment. It is sectional drawing which shows the state at the time of the die temperature at the time of extrusion of the mandrel of 2nd Embodiment. It is sectional drawing which shows the decomposition | disassembly state of the mandrel of 3rd Embodiment. It is sectional drawing which shows the state at the time of normal temperature of the mandrel of 3rd Embodiment. It is sectional drawing which shows the state at the time of the die temperature at the time of extrusion of the mandrel of 3rd Embodiment. It is explanatory drawing which shows the pressure distribution in the die temperature at the time of extrusion. It is a figure which shows the relationship between temperature, the outer diameter of a mandrel, and the inner diameter of a mandrel ring. In the mandrel of 1st Embodiment, it is sectional drawing at the time of normal temperature explaining fixation of the mandrel ring by a nut. It is sectional drawing which shows the state in the die temperature at the time of extrusion of FIG. 12A. In the mandrel of 1st Embodiment, it is sectional drawing at the time of normal temperature explaining fixation of the mandrel ring by a nut. It is sectional drawing which shows the state in the die temperature at the time of extrusion of FIG. 13A. It is sectional drawing which shows the decomposition | disassembly state of the mandrel of 4th Embodiment. It is sectional drawing which shows the state at the time of normal temperature of the mandrel of 4th Embodiment. It is sectional drawing which shows the state at the time of the die temperature at the time of extrusion of the mandrel of 4th Embodiment. It is sectional drawing which shows the other example of formation of the alkali resistant film of the mandrel ring of FIG. It is sectional drawing which shows the state at the time of normal temperature of the modification of the mandrel of 4th Embodiment. It is sectional drawing which shows the state at the time of the die temperature at the time of extrusion of the modification of the mandrel of 4th Embodiment.

  The port hole die (10) shown in FIGS. 1 and 2 is a combination of a female die (11) for molding the outer peripheral surface of the hollow extruded material (1) and a male die (20) for molding the inner peripheral surface. The male mold (20) is an embodiment of the extrusion die of the present invention.

  The female mold (11) has a bearing hole (12) in the center, a relief hole (13) is formed on the downstream side of the bearing hole (12), and a recess (14) for the welding chamber is formed on the upstream side. Is formed.

  The male mold (20) has a plurality of port holes (22) penetrating in the extrusion direction around the mandrel (30), with a mandrel (30) protruding downstream from the center of the die base (21). ing. Between the adjacent port holes (22) and (22), leg portions (23) for supporting the mandrel (30) protruding downstream by the base end portion (31) are formed.

  As shown in FIG. 3, in the mandrel (30), a mandrel (32) having a small diameter is integrally formed on the distal end side of the base end (31), and the base end (31) and the mandrel (32) Due to the difference in diameter, a step (33) is formed between them. The distal end side of the mandrel (32) is further reduced in diameter, and a bolt portion (34) having a helical thread groove formed on the outer peripheral surface is integrally formed. The base end portion (31), the mandrel (32) and the bolt portion (34) are formed coaxially. The mandrel ring (35) is an annular body in which a bearing portion (36) for forming the inner peripheral surface of the extruded material (1) projects from the outer peripheral surface. The nut (37) has a screw hole (38) screwed into the screw groove of the bolt part (34). Thus, the mandrel ring (35) is fitted onto the mandrel (32) and brought into contact with the stepped portion (33), and the screw hole (38) of the nut (37) is screwed into the bolt portion (34). The mandrel ring (35) is sandwiched between the step portion (33) and the nut (37), and is disposed at a predetermined position in the extrusion axis direction. The material properties and dimensions of the mandrel (32) and mandrel ring (35) will be described in detail later.

  When the female mold (11) and the male mold (20) are combined, the bearing portion (36) of the mandrel ring (35) of the male mold (20) is fitted into the bearing hole (12) of the female mold (11). An annular molding gap (not shown) is formed between them, and a part of the recess (14) for the welding chamber of the female mold (11) is blocked by the end face of the male mold (20), and the port hole ( 22) A welding chamber that communicates with is formed. Then, the extruded materials that have flowed into the respective port holes (22) merge in the welding chamber and are extruded from the forming gap as an extruded material (1) having a hollow portion (2).

The “die temperature during extrusion” in the present invention refers to the temperature at which the mandrel (32) and the mandrel ring (35) reach a predetermined temperature during high-temperature extrusion, and the temperature at that time. Further, “there is a gap (S ₁ )” between the mandrel (32) and the mandrel ring (35) does not mean the presence or absence of contact between the mandrel (32) and the mandrel ring (35), This means that the outer diameter (A _T1 ) of the mandrel at normal temperature (T ₁ ) and the inner diameter (B _T1 ) of the mandrel ring satisfy the relationship “B _T1 > A _T1 ”, and there is a clearance between them. . Also, room temperature _{(T 1)} the difference between the outer diameter _{(A T1)} of the inner diameter of the magnitude mandrel ring gap _{(S 1)} when the _{(35) (B T1)} and the mandrel ₍₃₂₎ (B _{T1 -A} T1 ). If the mandrel (32) and mandrel ring (35) are assembled in a posture where the axis of the mandrel is horizontal, the clearance is biased in the circumferential direction because the axes are not aligned, or the mandrel ring (35) and mandrel Although (32) may be in partial contact, the gap (S ₁ ) is (B _T1 -A _T1 ) even in such a case.

[Materials for mandrels]
In the present invention, the mandrel ring needs to have a hard alkali-resistant coating formed on at least the outer peripheral surface of the substrate. In the mandrel ring (35) in this embodiment, the entire surface of the base material (39a) is covered with a hard alkali-resistant coating (39b).

The material constituting the base material (39a) of the mandrel ring (35) is excellent in wear resistance, and its thermal expansion coefficient (α ₂ ) and the thermal expansion coefficient (α ₁ ) of the material constituting the mandrel (32) Is not particularly limited as long as the relationship of α ₁ > α ₂ is satisfied. In the present embodiment, the portion including the mandrel (32) (hereinafter simply referred to as “mandrel”) is formed of tool steel, whereas the base material (39a) of the mandrel ring (35) is the tool. It is made of a super hard material that has higher wear resistance than steel. Examples of the cemented carbide material include cemented carbide alloys such as WC-Co, high-speed tool steel, powdered high-speed tool steel, and ceramics. Table 1 shows an example of these superhard materials and tool steels and their thermal expansion coefficients. In addition, since the thermal expansion coefficient of the base (39a) of the mandrel (32) and the mandrel ring (35) only needs to satisfy the relationship of α ₁ > α ₂ , the exemplified materials are not limited to the uses described in Table 1. . For example, a case where a mandrel ring of cemented carbide or ceramics is combined with a mandrel of powder high-speed tool steel is also included in the present invention.

  The alkali-resistant coating (39b) prevents abrasion of the substrate (39a) during extrusion, and the substrate (39a) is not dissolved in a strong alkaline solution such as caustic soda used for washing in die maintenance after extrusion. Protect. Among the materials of the base material (39a), there is a material in which a part of the component is dissolved from the surface when it comes into contact with a strong alkaline solution. For example, in WC-Co, Co dissolves in a strong alkaline solution and is lost, and the elution of Co causes the surface strength to decrease and wear. In response to this phenomenon, in the present invention, an alkali-resistant coating (39b) is formed on the surface of the substrate (39a) to prevent dissolution of the components contained on the surface of the substrate (39a), thereby preventing the substrate (39a) from being worn. . Moreover, since the alkali-resistant coating (39b) has high hardness and wear resistance, the coating itself is prevented from being worn by extrusion, and the dissolution preventing effect can be maintained for a long time.

  The type of the alkali-resistant coating (39b) is not limited as long as it has alkali resistance and abrasion resistance, and the coating described in Table 2 can be exemplified. The alkali-resistant coating (39b) preferably has a hardness higher than that of the substrate (39a). For example, the HRA hardness of the cemented carbide (WC-Co) is about 85 (900 in HV hardness), and the preferable HV hardness of the alkali-resistant coating (39b) is 900 or more, particularly preferably 1800 or more. The wear resistance of the mandrel ring (35) can be further improved by forming the alkali-resistant coating (39b) having a hardness (39a) higher than that of the substrate (39a). All the coatings described in Table 2 have an HV hardness of 1800 or more. The thickness of the alkali-resistant coating (39b) is not limited, but is preferably 1 μm or more in order to obtain a sufficient effect. A particularly preferred thickness is 2 to 8 μm. The alkali-resistant coating (39b) can be formed by subjecting a base material (39a) molded into a predetermined shape to a known surface treatment such as CVD or PVD.

Further, in the mandrel ring (30), by the state of the die temperature during the extrusion (T ₂₎ and room temperature (T ₁₎ is repeated, the substrate (39a) is to repeat the expansion and contraction, of the If it is the thickness of an alkali-resistant film (39b), the film will not be cracked, and dissolution from the cracked part will not occur with the alkaline cleaning liquid.

In the mandrel (35), the alkali-resistant coating (39b) is formed not only on the outer peripheral surface of the mandrel ring (35) to which the extruded material adheres, but also on the inner peripheral surface and the end surface where wear resistance is not required. Is as follows. Since the die temperature at the time of washing is lower than the normal temperature (T ₁ ) or the temperature at the time of extrusion (T ₂ ), the mandrel (32) and the mandrel ring (35) shrink to each other, and the tightening margin is loosened. There is a gap (S ₁ ) between (see FIG. 5A). The cleaning liquid may enter the gap (S ₁ ) from the threaded portion of the bolt (34) of the mandrel (32) and the nut (37), and the inner peripheral surface of the mandrel ring (35) also contacts the cleaning liquid. there's a possibility that. When the inner peripheral surface of the mandrel ring (35) is melted and the inner diameter is enlarged, the fixing stability in the radial direction of the mandrel ring (35) is lowered, and the extrusion stability is lowered. For this reason, the alkali-resistant coating (39b) is also formed on the inner peripheral surface where the cleaning liquid may come into contact with the looseness of the tightening allowance.

When the mandrel ring is constrained by a holding member such as a nut from the downstream side in the axial direction as in this embodiment, both end surfaces of the mandrel ring (35) are the stepped portion (33) of the die base (31). And the nut (37) are strongly pressed, so the possibility of the cleaning liquid entering from these joints is very low, and the intrusion of the cleaning liquid which adversely affects the extrusion stability does not occur. Moreover, as will be described in detail later in [Fixing of the mandrel ring in the extrusion axis direction], when the die temperature (T ₂ ) during extrusion rises, the mandrel ring (35) loosens in the axial direction due to the difference in thermal expansion coefficient. as no ordinary temperature (T ₁₎ the nut (37) than when the high-temperature (T ₂₎ when the order is tightened strongly mandrel ring (35), the cleaning liquid entering through an end face of the mandrel ring (35) The possibility is even lower.

Therefore, in view of the state at normal temperature (T ₁ ), an alkali resistant coating (39b) is formed on the outer peripheral surface and inner peripheral surface of the base material (39a) as in the mandrel ring (80) shown in FIG. 4A. Therefore, even if the alkali-resistant coating (39b) is not formed on both end faces (81a) (81b), the possibility of the cleaning liquid coming into contact with the inner peripheral surface is extremely low, and the fixing stability of the mandrel ring (80) is improved. Do not decrease. The mandrel rings (35) and (80) in FIGS. 3 and 4A have a relief diameter larger than the diameter of the flange (37a) of the nut (37). Contact. Therefore, in the mandrel ring (80) of FIG. 4A in which the downstream end face (81b) is not covered with the alkali-resistant coating, the outer edge portion of the downstream end face (81b) contacts the cleaning liquid and is dissolved in the base material (39a). Arise. However, since the fixing stability of the mandrel ring is not deteriorated due to the dimensional change caused by the dissolution at the time of washing at the downstream end face, the alkali resistant coating on the end face is not an essential requirement. Therefore, in the mandrel having the above structure, it is sufficient that an alkali resistant coating is formed on the outer peripheral surface and inner peripheral surface of the base material of the mandrel ring, and when a mandrel ring having no alkali resistant coating formed on both end surfaces is used. However, the fixing stability is not impaired by washing, and stable extrusion can be repeated.

  Further, the present invention does not exclude the alkali resistant coating on the end surface of the mandrel ring, but the mandrel ring (35) in which the alkali resistant coating (39b) is formed on the entire surface of the base material (39a) shown in FIG. 4B and FIG. 4C, a mandrel ring (82) in which an alkali-resistant coating (39b) is formed only on one of the upstream end surface (81a) and the downstream end surface (81b) of the substrate (39a) (84) is also included in the present invention.

  In addition, if the downstream end face of the mandrel ring does not adversely affect the fixation stability even if it melts, the life of the mandrel ring will be as long as possible, and the outer edge of the downstream end face will be more than dissolved. It is clear that it is preferable not to dissolve. As shown in Fig. 4D, the diameter of the flange (37b) of the nut (37) is increased to the same diameter as the relief diameter of the mandrel ring (80). 37b) recommends a structure that covers the end face of the mandrel ring (80). Moreover, like the mandrels (35) and (82) in FIGS. 3 and 4B, an alkali-resistant coating (39b) is formed on the downstream end face (81b) of the base material (39a) to protect the base material (39a). It is also preferable.

  Furthermore, when the cleaning liquid does not contact the inner peripheral surface of the mandrel ring, an alkali resistant coating on the inner peripheral surface is not an essential condition. For example, in the mandrel (60) of the fourth embodiment described later, the mandrel (61) is detachable from the base (24) of the base part (21), and the mandrel ring (35) is attached to the main body (62) of the mandrel (61). The head (64) for restraining the mandrel ring (35) from the downstream side is formed integrally with the main body (62) (see FIGS. 14 to 15B). Since the mandrel (61) has no threaded portion at the head corresponding to the nut (37) of the mandrel (30) in FIG. 3, the cleaning liquid does not enter from the downstream side. Also, since both end surfaces of the mandrel ring (35) are strongly pressed by the pedestal (24) and the flange (67) of the head (64), the cleaning liquid is applied from both end surfaces as in the mandrel (30) of FIG. There is no intrusion. Therefore, the inner peripheral surface (35a) of the mandrel ring (35) does not contact the cleaning liquid. Therefore, in the mandrel structure in which the cleaning liquid does not enter from the front end side of the mandrel, as shown in FIG. 16, an alkali resistant coating (39b) is formed only on the outer peripheral surface of the base material (39a), and the upstream end surface (81a), A mandrel ring (86) that does not form an alkali-resistant coating (39b) on the downstream end face (81b) and the inner peripheral face (81c) can be used.

  Therefore, in the mandrel ring in the present invention, it is an essential requirement that an alkali-resistant coating is formed on the outer peripheral surface, but in other aspects, the necessity of coating is determined according to the structure of the mandrel.

  In the mandrel ring, the merit of not forming the alkali resistant coating on a part of the surface of the substrate is the cost reduction of the surface treatment for forming the alkali resistant coating. The CVD and PVD exemplified above as surface treatment methods are advantageous in terms of cost because there is a difference in treatment costs between the treatment for forming a coating on the entire surface and the treatment for not forming a coating on some surfaces. However, there is no inconvenience even if an alkali-resistant coating is present on the surface that does not adversely affect the fixation stability of the mandrel ring, so that the protective effect on the base material is further enhanced, or contact with an unintentional cleaning liquid or mandrel It is not necessarily useless to form an alkali-resistant coating on the end face or inner peripheral surface in preparation for disassembly and cleaning.

In the present invention, since there is a gap between the mandrel ring and the mandrel ring at room temperature (T ₁ ), the mandrel ring can be easily attached to and detached from the mandrel, and maintenance such as replacement of the mandrel ring can be easily performed. And since it is possible to re-form the alkali-resistant film against the mandrel ring removed from the mandrel, the strength of the mandrel ring is increased by the protective effect of the base material by the alkali-resistant film and the re-formation of the alkali-resistant film. The life span can be extended by maintaining the period.

  In the present invention, by using a material having a smaller coefficient of thermal expansion than that of the mandrel as the base material for the mandrel ring, the expansion coefficient of the mandrel ring due to processing heat generated during extrusion is reduced. Can be obtained. In other words, in the mandrel with a mandrel ring with a small thermal expansion coefficient combined with a mandrel (tool steel), the outer diameter difference between the unextruded and the maximum processing heat generation is larger than the outer diameter difference in the mandrel manufactured with only tool steel. Since it becomes smaller, the thickness of the extruded material is stabilized. And if the dimension of an extrusion material is stable, the product quality after post-processing will also become stable. For example, when drawing is performed after extrusion, if the extruded material has no uneven thickness and the thickness is constant, the thickness of the drawn material is also constant. In addition, if the thickness of the extruded material is constant, the length of drawing is also constant. Moreover, since the alkali-resistant film described above has high wear resistance, the generation of wear powder is small, and the mixing of the wear powder into the extruded material is also reduced. If the die wear powder, which is a foreign substance, is mixed in the extruded material, the quality of the extruded material is deteriorated and it becomes a surface defect of the drawn material. If the amount of wear powder mixed into the extruded material is small, surface defects generated in the drawn material are also reduced. From these facts, the extruded material produced using the extrusion die of the present invention is excellent not only in quality as an extruded material but also in quality as a post-processing material.

[Mandrel shape]
The mandrel of the present invention has a gap between the mandrel ring and the mandrel at room temperature, and there is no gap at least in the axial direction of the mandrel at the die temperature during extrusion. As long as it is set to do, the shape of the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring can be arbitrarily set. That is, the conditions regarding the shape of the mandrel in the present invention are the following (1) and (2).
(1) There is a gap that allows the mandrel ring to be fitted onto the mandrel at room temperature. (2) At the die temperature during extrusion, the mandrel ring comes into contact with the mandrel ring at least partly in the axial direction. The following shows examples of mandrel shapes that can be set in the present invention. Moreover, the dimension of a mandrel ring is a dimension containing an alkali-resistant film.

(First embodiment)
3 and 5A are cross-sectional views of the main part of the mandrel (30) at normal temperature (T ₁ ). This mandrel (30) is a mandrel constituting a part of the male die (20) of the extrusion die (10) shown in FIGS.

The mandrel (30) has an outer peripheral surface (32a) of the mandrel (32) and an inner peripheral surface (35a) of the mandrel ring (35) formed in parallel to the axis of the mandrel (30), and the outer diameter of the mandrel (32). (A _T1 ) and the inner diameter (B _T1 ) of the mandrel ring (35) are constant in the axial direction. When the mandrel ring (35) is externally fitted to the mandrel (32), a certain gap (S ₁ ) parallel to the axis exists between the two.

When assembling the mandrel (32) and mandrel ring (35) at room temperature (T ₁ ), it is easy to fit the mandrel ring (35) to the mandrel (32) because of the gap (S ₁ ). is there. Further, when the nut (37) is attached and tightened, the mandrel ring (32) generates a tensile force in the extrusion direction, and the mandrel ring (35) generates a compression force in the extrusion direction.

(Second Embodiment)
6 and 7A are cross-sectional views of the main part of the mandrel (40) at normal temperature (T ₁ ). This mandrel (40) is an alternative to the mandrel (30) of the first embodiment in the male die (20) of the extrusion die (10) shown in FIGS. In FIGS. 6 to 7B, the same reference numerals as those in FIGS. 1 to 5B denote the same components, and redundant description is omitted.

The mandrel (40) forms the outer peripheral surface (32a) of the mandrel (32) parallel to the axis of the mandrel (40), while the inner peripheral surface (45a) of the mandrel ring (45) is directed toward the downstream side. It is formed with a tapered surface (taper angle: θ _T1 ) that is inclined outward. When the mandrel ring (45) is externally fitted to the mandrel (32), between the mandrel (32) and the mandrel ring (45), the upstream end of the extrusion (the base of the mandrel) is the narrowest and the downstream side (mandrel) There is a gap (S ₁ ) that gradually widens toward the tip end side.

  The mandrel (40) of the present embodiment and the mandrel (30) of the first embodiment share a mandrel (32), and the angle of the inner peripheral surfaces (35a) (45a) of the mandrel rings (35) (45) is Different. The mandrel ring (45) has an alkali resistant coating (49b) formed on the entire surface of the substrate (49a).

FIG. 7A shows the diameter at the upstream end where the diameter is minimum as the inner diameter (B _T1 ) of the mandrel ring (45) at normal temperature (T ₁ ). The outer diameter (A _T1 ) of the mandrel (32) is constant in the axial direction. Therefore, a gap (S ₁ ) having a minimum value (B _T1 −A _T1 ) exists between the outer peripheral surface (32a) of the mandrel (32) and the inner peripheral surface (35a) of the mandrel ring (35). To do.

When assembling the mandrel (32) and mandrel ring (35) at room temperature (T ₁ ), it is easy to fit the mandrel ring (35) to the mandrel (32) because of the gap (S ₁ ). is there. Further, when the nut (37) is attached and tightened, the mandrel ring (32) generates a tensile force in the extrusion direction, and the mandrel ring (35) generates a compression force in the extrusion direction.

(Third embodiment)
8 and 9A are cross-sectional views of the main part of the mandrel (50) at normal temperature (T ₁ ). This mandrel (50) is an alternative to the mandrel (30) of the first embodiment in the male die (20) of the extrusion die (10) shown in FIGS. In FIGS. 8 to 9B, the same reference numerals as those in FIGS. 1 to 5B denote the same components, and redundant description is omitted.

The mandrel (50) forms the inner peripheral surface (35a) of the mandrel ring (35) parallel to the axis of the mandrel (30), while the outer peripheral surface (52a) of the mandrel (52) faces toward the downstream side. It is formed with a tapered surface inclined outward. In these dimensions, there is a gap (S ₁ ) between the outer peripheral surface (52a) of the mandrel (52) and the inner peripheral surface (35a) of the mandrel ring (35), and the gap (S ₁ ) is extruded. It is set so that it gradually narrows toward the downstream side (the tip end side of the mandrel) and becomes the narrowest at the downstream end, and gradually widens toward the upstream side (the base side of the mandrel) and widens at the upstream end. ing.

  The mandrel (50) of the present embodiment and the mandrel (30) of the first embodiment have the same mandrel ring (35) and different angles of the outer peripheral surfaces (32a) (52a) of the mandrels (32) (52). .

FIG. 9A shows the diameter at the downstream end where the diameter becomes the maximum as the outer diameter (A _T1 ) of the mandrel (52) at normal temperature (T ₁ ). The inner diameter (B _T1 ) of the mandrel ring (35) is constant in the extrusion direction. Therefore, a gap (S ₁ ) having a minimum value (B _T1 −A _T1 ) exists between the outer peripheral surface (32a) of the mandrel (32) and the inner peripheral surface (35a) of the mandrel ring (35). To do.

When assembling the mandrel (52) and the mandrel ring (35) at room temperature (T ₁ ), it is easy to fit the mandrel ring (35) to the mandrel (52) because of the gap (S ₁ ). is there. Further, when the nut (37) is attached and tightened, a tensile force in the extrusion direction is generated in the mandrel (52), and a compressive force in the extrusion direction is generated in the mandrel ring (35).

[Fixing in the radial direction of the mandrel ring]
FIG. 11 shows changes in the outer diameter (A) of the mandrels (32) and (52) and the inner diameter (B) of the mandrel rings (35) and (45) with respect to the temperature (T). In the three types of mandrels (30), (40) and (50) described above, the inner peripheral surface (45a) of the mandrel ring (45) of the second embodiment and the outer peripheral surface of the mandrel (52) of the third embodiment ( 52a) is a tapered surface, and its inner diameter (B) and outer diameter (A) change in the axial direction, so here the mandrel (32) (52) and the mandrel ring (35) (45) The outer diameter (A) of the mandrels (32) and (52) and the inner diameter (B) of the mandrel rings (35) and (45) in the portion where the clearance between the mandrel and the mandrel rings is minimized. That is, the mandrel (30) of the first embodiment is the outer diameter (A) of the mandrel at an arbitrary portion and the inner diameter (B) of the mandrel ring, and the mandrel (40) of the second embodiment is the mandrel at the upstream end. The outer diameter (A) of (32) and the inner diameter (B) of the mandrel ring (45). In the mandrel (50) of the third embodiment, the outer diameter (A) of the mandrel (52) and the mandrel ring at the downstream end It is an inner diameter (B) of (35).

Both the mandrel (32) (52) and the mandrel ring (35) (45) expand in size due to thermal expansion (A _T , B _T ). As shown in this figure, at normal temperature (T ₁ ), the inner diameter (B _T1 ) of the mandrel ring is larger than the outer diameter (A _T1 ) of the mandrel, and there is a gap of B _T1 -A _T1 as an actual size. When the temperature (T) rises, the mandrel (32) (52) and the mandrel ring (35) (45) depend on the thermal expansion coefficients (α ₁ ) (α ₂ ) of the respective substrates (39a) (49a). The diameter increases. T _2> outer diameter _{(A T2)} and the mandrel inside diameter of the ring (35) (45) of the mandrel (32) (52) at any temperature that satisfies _{T 1 (T 2) (B} T2) are the following ( It is represented by the formulas (I) and (II).

A _T2 = A _T1 × (T ₂ −T ₁ ) × α ₁ + A _T1 (I)
B _T2 = B _T1 × (T ₂ −T ₁ ) × α ₂ + B _T1 (II)
Where α ₁ : coefficient of thermal expansion of the material constituting the mandrel
α ₂ : Thermal expansion coefficient of the material constituting the base material of the mandrel ring
T ₁ : normal temperature
T ₂ : High temperature (> T ₁ )
A _T1 : Outer diameter of the mandrel at normal temperature (T ₁ )
B _T1 : Inner diameter of mandrel ring at normal temperature (T ₁ ) (> A _T1 )

If the inner diameter (B _T1 ) of the mandrel ring (35) (45) is made larger than the outer diameter (A _T1 ) of the mandrel (32) (52) at normal temperature (T ₁ ), the mandrel ( Since there is a gap (S ₁ ) between the outer peripheral surface of 32) and the inner peripheral surface of the mandrel ring (35) (45), it can be easily fitted.

When the die temperature rises, the clearance (S ₁ ) decreases because the outer diameter expansion amount of the mandrel (32) (52) exceeds the inner diameter expansion amount of the mandrel ring (35) (45). When (S ₁ ) disappears, the mandrel ring (35) (45) is fixed to the mandrel (32) (52).

Since the thermal expansion coefficient is α ₁ > α ₂ , as shown in FIG. 11, the outer diameter (A _TZ ) of the mandrel (32) (52) and the mandrel ring at the temperature (T _Z ) as the temperature rises. When the inner diameters (B _TZ ) of (35) and (45) become equal, the gap (S ₁ ) disappears, and the mandrel rings (35) and (45) cannot be detached from the mandrels (32) and (52) and are fixed. It becomes. When the temperature further increases, the outer diameter (A _T ) of the mandrel (32) (52) exceeds the inner diameter (B _T ) of the mandrel ring (35) (45). In the temperature range (T> T _Z ) where the outer diameter (A _T ) of the mandrel (32) (52) exceeds the inner diameter (B _T ) of the mandrel ring (35) (45), the expansion of the mandrel (32) (52) The force acts as a force to tighten the mandrel ring (35) (45) from the inside, and a tensile force is applied to the mandrel ring (35) (45) in the circumferential direction. It becomes difficult and is fixed firmly.

(First embodiment)
Mandrel (30), since the gap at the normal temperature (T ₁₎ (S ₁₎ is parallel to the axis, a gap in the process of die temperature increases (S ₁₎ is gradually narrowed while remaining parallel, T ≧ T outer peripheral surface of the _Z becomes a gap in a temperature range (S ₁₎ is missing mandrel (32) (32a) and the inner peripheral surface of the mandrel ring (35) (35a) are in contact with the entire surface (see FIG. 5B).

(Second Embodiment)
In the mandrel (40), the gap (S ₁ ) at normal temperature (T ₁ ) is narrower toward the upstream side, so in the process of increasing the die temperature, first the gap (S ₁ ) at the upstream end of the mandrel (32). ) Disappears, and the region without the gap (S ₁ ) expands downstream (see FIG. 7B). The contact surface (41) formed on the upstream side is an inclined surface inclined outward toward the downstream side along the inner peripheral surface (45a) of the mandrel ring (45) at normal temperature (T ₁ ). Become.

In this embodiment, as shown in FIG. 7B, at the die temperature (T ₂ ) during extrusion, the mandrel ring (32) and the mandrel ring (45) are in contact with each other on the upstream side, and the gap (S ₁ ) is formed on the downstream side. The inner diameter (B _T1 ) and the taper angle of the inner peripheral surface (45a) at the upstream end of the mandrel ring (45) and the outer diameter (A _T1 ) of the mandrel (32) are set so as to remain. It is not limited to such a dimension setting. It is sufficient if the contact surface is inclined outward toward the downstream side of the extrusion, and the mandrel ring and the mandrel ring can be contacted in the whole area, or in the upstream or intermediate part, depending on the above-mentioned dimension setting. The case where contact is made at a plurality of locations is also included in the present invention. Furthermore, the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are not limited to being smooth surfaces, and a contact structure that causes a protrusion provided on one side to bite into the other is also included in the present invention.

(Third embodiment)
Mandrel (50), the gap at the normal temperature (T ₁₎ (S ₁₎ so is narrower toward the downstream side, the gap in the process of die temperature increases, the first downstream end of the mandrel (52) (S ₁ ) Disappears, and the region without the gap (S ₁ ) expands upstream (see FIG. 9B). Since the gap (S ₁ ) at the normal temperature (T ₁ ) is narrower toward the downstream side, the mandrel ring (35) is tightened with a greater force toward the downstream side at the die temperature (T ₂ ) during extrusion. For this reason, as shown in FIG. 9, a difference appears in the stress field applied to the interface between the outer peripheral surface (52a) of the mandrel (52) and the inner peripheral surface (35a) of the mandrel ring (35), and the pressure decreases toward the downstream side. Higher and lower on the upstream side. And the force (F) opposite to an extrusion direction acts by such a difference in pressure distribution. This reverse force (F) acts against the force that the extruded material pushes the mandrel ring (35) downstream, so that the downstream movement of the mandrel ring (35) during extrusion is suppressed, and the mandrel The positional stability of the ring (35) is improved.

In this embodiment, as shown in FIG. 9B, at the die temperature (T ₂ ) at the time of extrusion, the mandrel (52) and the mandrel ring (35) are in contact on the downstream side, and the gap (S ₁ ), The inner diameter (B _T1 ) of the mandrel ring (35), the outer diameter (A _T1 ) at the downstream end of the mandrel (52), and the taper angle of the outer peripheral surface (32a) are set. However, the present invention is not limited to such dimension setting. The above effect can be obtained if the gap at normal temperature is set to be narrow on the downstream side of the extrusion, so that the outer peripheral surface of the mandrel parallel to the axis and the inner periphery of the mandrel ring inclined inward toward the downstream side Combinations with surfaces, combinations of tapered surfaces with different inclination directions, and combinations of tapered surfaces with different angles inclined in the same direction are also included in the present invention. Further, the present invention also includes a case where the mandrel and the mandrel ring are in contact with each other in the entire region. Furthermore, it is not limited that the size of the gap changes in the entire area in the extrusion direction, and a centering portion in which the size of the gap (S ₁ ) is constant is provided in a part of the axial direction. Is also possible.

In the present invention, it is not an essential condition that the mandrel and the mandrel ring come into contact with each other at the die temperature (T ₂ ) at the time of extrusion. This is shown in the second and third embodiments. However, the larger the contact area between the two, the more the tightening force is applied and the fixing stability of the mandrel ring is improved. Therefore, 20% or more, particularly 50% or more, of the inner peripheral surface of the mandrel ring contacts the outer peripheral surface of the mandrel. It is preferable to do. Such a contact area ratio can be adjusted by material selection and sizing of the base material of the mandrel and mandrel ring.

(Tightening of mandrel and mandrel ring)
At the time of extrusion, the die is heated to a predetermined temperature and becomes higher than normal temperature (T ₁ ). Therefore, as shown in FIGS. 5B, 7B, and 9B, at the die temperature (T ₂ ) during extrusion, the outer diameter (A _T2 ) of the mandrel (32) (52) is equal to the inner diameter (35) (45) of the mandrel ring (35) (45). B _T2) and equal or, to exceed the mandrel (32) (52 outer diameter) _{(a T2)} mandrel ring (35) (45) inside diameter _{(B T2)} of the mandrel when the room temperature _{(T 1)} (32) by setting the inner diameter _{(B T1)} of the outer diameter of (52) _{(a T1)} and the mandrel ring (35) (45), the mandrel ring (35) (45) to the mandrel (32) (52) Extrusion can be performed in a fixed state. When extrusion is performed with the mandrel rings (35) and (45) being fixed to the mandrel (32) and (52), uneven thickness of the extruded material (1) is suppressed and a high quality extruded material (1) is obtained. Can be manufactured. However, if the expansion force of the mandrel (32) (52) becomes excessive and exceeds the limit of the tensile force of the mandrel ring (35) (45), the mandrel ring (35) (45) will be damaged. Considering the coefficient (α ₁ , α ₂ ) and the die temperature (T ₂ ) at the time of extrusion, the mandrel (32) (52) at normal temperature (T ₁ ) is generated so as to generate an appropriate tensile force at high temperatures. The outer diameter (A _T1 ) and the inner diameter (B _T1 ) of the mandrel rings (35) and (45) are set.

Here, the degree of tightening and loosening of the mandrel (32) (52) and the mandrel ring (35) (45) at an arbitrary temperature (T) is defined as the outer diameter (A _T ) of the mandrel (32) (52). Based on the ratio of the inner diameter (B _T ) of the mandrel rings (35) and (45), it is defined as a tightening allowance (X _T ) in the following formula (III). When A _T <B _T , that is, when there is a gap between the two, X _T <0, indicating that the looseness increases as the tightening allowance (X _T ) value decreases. On the other hand, when A _T > B _T , that is, there is no gap between the two and the mandrel ring (35) (45) is clamped from the inside to the mandrel (32) (52), X _T > 0, It shows that the tightening force increases as the value of (X _T ) increases. A _T = B _T (X _T = 0) is a state in which there is no gap between the two but the tightening force is not effective.
X _T (%) = (A _T / B _T −1) × 100 (III)

Further, according to the formula (III), the allowance between the mandrel (32) (52) and the mandrel ring (35) (45) at normal temperature (T ₁ ) and high temperature (T ₂ ) (die temperature during extrusion) ( X _T1 ) (X _T2 ) are represented by the formulas (IV) and (V), respectively.
X _T1 (%) = (A _T1 / B _T1 −1) × 100 (VI)
X _T2 = (A _T2 / B _T2 −1) × 100
= {[A _T1 × (T ₂ −T ₁ ) × α ₁ + A _T1 ] / [B _T1 × (T ₂ −T ₁ ) × α ₂ + B _T1 ] −1} × 100
… (V)

Since the mandrel (32) (52) and the mandrel ring (35) (45) are manufactured so that A _T1 <B _T1 at room temperature (T ₁ ), X _T1 <0 and the tightening allowance (X _T1 ) is It shows a loose state with a gap between them. On the other hand, since there is no gap between the _two at the die temperature (T ₂ ) at the time of extrusion and A _T2 ≧ B _T2 , the tightening allowance (X _T2 ) is 0 or a positive value, and the tightening force is effective. Show. Further, X _T2 <0 indicates that the mandrel rings (35) and (45) are not fixed to the mandrels (32) and (52) due to looseness even at the die temperature (T ₂ ) during extrusion.

As the tightening allowance (X _T2 ) increases, the tightening force also increases, and the mandrel ring (35) (45) is firmly fixed and difficult to come off. However, as described above, the mandrel ring (35) becomes excessively large. (45) may be damaged. Further, during extrusion, a force in the extrusion direction is also applied due to the material flow. Taking these into account, the fastening allowance (X _T2 ) is preferably 0.3% or less. As long as the tightening allowance (X _T2 ) is 0 or a positive value, the lower limit value is not specified, but 0.05% or more is preferable in order to fix it securely. A particularly preferred interference (X _T2 ) is 0.15 to 0.25%. The appropriate range of the tightening allowance (X _T2 ) varies depending on the material of the mandrels (32) (52) and the mandrel rings (35) (45), the thickness of the mandrel rings (35) (45), and the like.

Accordingly, the tightening allowance (X _T2 ) at high temperature (T ₂ ) is 0 in the portion where the gap (S ₁ ) is minimum at normal temperature (T ₁ ) and the tightening force is maximum at the die temperature (T ₂ ) during extrusion. mandrel such that 0.3% (32) outside diameter _{(a T1)} and the mandrel ring (52) (35) (45) may be set to an inner diameter _{(B T1)} of the. The tightening allowance in the other portions is a value corresponding to the size of the gap (S ₁ ) at normal temperature (T ₁ ).

Further, the tightening allowance (X _T1 ) at normal temperature (T ₁ ) is not limited as long as it is a negative value. Since the outer diameters (A _T1 ) of the mandrels (32) and (52) are smaller than the inner diameters (B _T1 ) of the mandrel rings (35) and (45), these assembling operations are easy. When the extrusion die is finished and cooled to the normal temperature (T ₁ ), the extrusion die returns to the tightening allowance (X _T1 ) at the normal temperature (T ₁ ) and loosens, so that the mandrel ring ( 35) (45) can be removed. Accordingly, maintenance such as removal of a worn mandrel ring and installation of a new mandrel ring can be easily performed.

  5A, 5B, 7A, 7B, 9A, and 9B are schematic diagrams for explaining the thermal expansion in the radial direction, and the thermal expansion in the extrusion axis direction is not shown.

[Fixing of the mandrel ring in the extrusion axis direction]
In the mandrel (30) (40) (50) of the above embodiment, the nut (37) having a diameter larger than the inner diameter of the mandrel ring (35) (45) is detachable at the tip of the mandrel (32) (52). Is attached. The mandrel ring (35) at a high temperature (T ₂ ) is fixed by being clamped in the radial direction by the mandrel (32) (52), but during the extrusion, a downstream force is applied by the material flow. Therefore, in the mandrels (30), (40), and (50), the nuts (37) are attached to reliably prevent the mandrel rings (35) and (45) from falling off, thereby improving the fixing stability. Also, by attaching a nut (37) and applying a restraining force in the direction of the extrusion axis, the tightening allowance (X _T2 ) can be made smaller than when fixing only by tightening with the expansion force of the mandrel (32) (52). Therefore, the risk of breakage of the mandrel rings (35) and (45) due to an increase in the tightening allowance (X _T2 ) can be avoided.

In addition, in the mandrels (30), (40) and (50) to which the nut (37) is attached, the dimensions in the direction of the extrusion axis of the mandrel (32) and the mandrel rings (35) and (45) are also different at normal temperature (T ₁ ). It is preferable that the nut (37) abuts on the mandrel ring (35) at high temperature (T ₂ ) so that the mandrel ring (35) (45) is securely restrained by the nut (37). .

12A and 12B illustrate the mandrel (30) of the first embodiment and illustrate a preferable dimensional relationship in the extrusion axis direction of the mandrel (32) and the mandrel ring (35). At the normal temperature (T ₁ ) shown in FIG. 12A, the length of the mandrel (32) is shorter than the length of the mandrel ring (35), and the nut (37) screwed into the bolt part (34) is the mandrel ring (35 ) Is tightened. The mandrel ring (35) is constrained in the direction of the extrusion axis by applying a tensile force according to the gap (S ₂ ) between the mandrel (32) and the nut (37) to the mandrel (32). FIG. 12B is a diagram showing a state at the time of the die temperature (T ₂ ) at the time of extrusion in FIG. 12A, and shows a state where the mandrel (32) and the mandrel ring (35) are expanded. Since mandrel substrate in thermal expansion coefficient (32) (alpha ₁₎ and mandrel ring (35) coefficient of thermal expansion (39a) (alpha ₂₎ have a relationship of α _1> α _2, the dimensions of the mandrel (32) The expansion amount exceeds the dimensional expansion amount of the mandrel ring (35), and the gap (S ₂ ) changes in the decreasing direction. By reducing this gap (S ₂ ), the tensile force applied to the mandrel (32) is reduced and the clamping force on the mandrel ring (35) is reduced, but as long as there is a gap (S ₂ ), the nut (37) Therefore, the mandrel ring (35) does not shift in the direction of the extrusion axis. That is, the mandrel ring (35) is constrained and fixed in both the radial direction and the extrusion axis direction. As described above, the restraint in the direction of the extrusion shaft is added, so that the fixing stability of the mandrel ring (35) can be maintained even if the above-described radial interference (X _T2 ) is reduced. As a result, the tensile force in the circumferential direction applied to the mandrel ring (35) can be reduced, and damage due to an increase in the tightening allowance (X _T2 ) can be avoided.

In contrast, in FIG. 13A, the lengths of the mandrel (32) and the mandrel ring (35) are equal at room temperature (T ₁ ), and there is no gap (S ₂ ) between the mandrel (32) and the nut (37). Indicates the state. FIG. 13 is a diagram showing a state at the die temperature (T ₂ ) at the time of extrusion shown in FIG. 13A, and the mandrel ring (32) becomes longer than the mandrel ring (35) due to thermal expansion, and the mandrel ring (35) and the nut There is a gap (S ₃ ) between (37) and (37). In such a state, the mandrel ring (35) is not restrained by the nut (37), and the fixing stability in the direction of the extrusion shaft is lowered. Further, in order to reliably prevent the mandrel ring (35) from shifting in such a state, it is necessary to sufficiently increase the radial tightening allowance (X _T2 ), and thus the mandrel ring (35) may be damaged. The sex also increases.

12A and 12B show a case where the mandrel (32) is shorter than the mandrel ring (35) at room temperature (T ₁ ), but the difference is small and the length is reversed at the die temperature (T ₂ ) during extrusion. If the mandrel (32) is longer than the mandrel ring (35), the nut (37) cannot be suppressed as shown in FIG. 13B.

Thus, to act nut (37) by clamping force to the mandrel ring (35) at a die temperature during the extrusion (T _2), ambient temperature (T ₁₎ when the mandrel (32) and the mandrel ring (35) It is preferable to set the dimension in the direction of the extrusion axis. With increasing temperature of the die, the nut (37) the mandrel ring (35) is so changed in the loosening direction, in order to cock reliably die temperature (T ₂₎ during the tightening force by the nut (37) at the time of extrusion The nut (37) needs to tighten the mandrel ring (35) at least at normal temperature (T ₁ ). In the mandrel (50) of the second embodiment and the mandrel (50) of the third embodiment, the dimension setting for applying the tightening force by the nut (37) is the same as that of the mandrel (30) of the first embodiment.

  Further, in the mandrels (40) and (50) of the second and third embodiments, the inner peripheral surface (45a) of the mandrel ring (45) or the outer peripheral surface (52a) of the mandrel (52) is formed as a tapered surface. As a result, the retaining effect of the mandrel ring (45) (35) is obtained.

In the mandrel (40) of the second embodiment, the inner peripheral surface (45a) of the normal temperature (T ₁ ) mandrel ring (45) is tapered outwardly toward the downstream side with respect to the axis of the mandrel (40). The contact surface (41) at the time of the die temperature (T ₂ ) during extrusion is also an outer surface that extends toward the downstream side along the inclination direction of the inner peripheral surface (45a) of the mandrel ring (45). It becomes an inclined surface of direction (refer FIG. 5B). For this reason, even if the flow of the extruded material tries to push the mandrel ring (45) to the downstream side, the outward inclined surface (contact surface) (41) acts in a direction to prevent the movement, thereby providing a retaining effect. . Therefore, the movement of the mandrel ring (45) is suppressed and high fixing stability is obtained. Position of the contact surface (41), ambient temperature _{(T 1)} the size and the coefficient of thermal expansion of the gap _{(S 1)} when the (alpha _1, alpha ₂₎ Since determined by the difference of the normal temperature _{(T 1)} at the upstream side In the present embodiment having a gap (S ₁ ) that narrows toward the bottom, the inclination angle (θ _T2 ) is the taper angle (θ _T1 ) of the inner peripheral surface (45a) of the mandrel ring (45) at normal temperature (T ₁ ). ) Slightly, but the tilt direction is maintained.

If the contact surface (41) is slightly inclined, the above-described retaining effect can be obtained. Therefore, the present invention does not limit the inclination angle (θ _T2 ) of the contact surface (41). However, since the more the effect angle of inclination with respect to the axis (theta _T2) is larger mandrel (40) of the contact surface (41) increases, the inclination angle (theta _T2) is preferably from 0.05 to 3 °, in particular 0 .1 to 2 ° is preferable.

In addition, since the mandrel (40) of the present embodiment has a structure in which the mandrel ring (45) is externally fitted from the distal end side (downstream side) of the mandrel (32), the mandrel ring can be secured and secured with a contact area between the two. Taking into account the minimum diameter of (45) and the maximum diameter of the mandrel (32), the taper angle (θ _T1 ) at room temperature (T ₁ ) is naturally limited, and the inclination angle (θ _T2 ) of the contact surface (41) is also Limited to the corresponding angle. However, the taper angle (θ _T1 ) and the inclination angle (θ _T2 ) are increased if the mandrel ring is fitted to the mandrel ring from the base side (upstream side) of the mandrel so as to be detachable from the base end. be able to. The mandrel having such a structure will be described later in detail in the fourth embodiment.

  In the mandrel (50) of the third embodiment, as shown in FIG. 10, the mandrel ring (35) is moved in the axial direction by the force (F) generated by the difference in pressure distribution that tightens the mandrel ring (35) in the radial direction. Is also restrained, so that a retaining effect can be obtained.

[Positioning of the mandrel ring in the circumferential direction]
In the mandrel, the rotation of the mandrel ring in the circumferential direction can be prevented by forming the mandrel ring and the mandrel ring in a non-circular cross section. As a result, the circumferential displacement is eliminated, the fixing stability is improved, and the mandrel ring can be positioned. In particular, when the shape of the hollow part of the extruded material is other than a circle, positioning in the circumferential direction is required, and thus the application significance is great.

[Removal of mandrel]
In the present invention, the mandrel mandrel can be detachably attached to the base portion of the die.

(Fourth embodiment)
A mandrel (60) shown in FIGS. 14 to 15B has a mandrel (61) that is detachably attached to a base (24) that continues from the base (21) of the male mold (20) referred to in FIG. And a mandrel ring (35) fitted on the mandrel (61). 14 to 15B, the same reference numerals as those in FIGS. 1 to 5B denote the same components, and redundant description is omitted.

  The mandrel (61) has a bolt shape, and a convex part (63) for attaching the mandrel (31) to the pedestal (24) on the upstream side of the body part (62), which is a mounting part of the mandrel ring (35) Is provided coaxially with the main body (62), and on the downstream side, a head (64) for suppressing the mandrel ring (35) is provided. On the other hand, the mandrel ring (35) is the same as in the first embodiment. Then, when the mandrel ring (35) is fitted from the convex part (63) side of the mandrel (61) and the convex part (63) is attached to the base (24), the mandrel ring (35) fitted to the main body part (62) is fitted. ) Is sandwiched between the tip surface of the pedestal (24) and the head (64) of the mandrel (61) and is arranged at a predetermined position in the axial direction. In this embodiment, the mandrel ring (35) is fixed to the mandrel (61) at the die temperature during extrusion by both the material and shape of the mandrel (61) and mandrel ring (35).

14 and 15A are cross-sectional views of the main part of the mandrel (60) at normal temperature (T ₁ ).

The body (62) of the mandrel (61) has a cylindrical shape with an outer diameter (A _T1 ), and the outer peripheral surface (62a) is parallel to the axis of the mandrel (61), that is, the axis of the mandrel (60). It is. The convex part (63) is smaller in diameter than the main body part (62), the part following the main body part (62) is a cylindrical centering part (65), and its outer peripheral surface is the axis of the mandrel (61) I.e. parallel to the axis of the mandrel. The upstream side of the centering portion (65) is a male screw portion (66) having a smaller diameter. The head (64) is larger than the inner diameter of the mandrel ring (35) and suppresses the mandrel ring (35) fitted to the main body (62) from the downstream side. The head (64) has a large-diameter flange (67) formed in a portion following the main body (62).

  On the other hand, a concave portion (25) corresponding to the convex portion (63) of the mandrel (61) is provided on the distal end surface of the base (24). The recess (25) is a centering portion (26) corresponding to the centering portion (65) of the mandrel (61) having an inner peripheral surface whose opening side (downstream side) is parallel to the axis, The upstream side) is a female thread part (27) corresponding to the male thread part (66) of the mandrel (61). Both the inner peripheral surface of the centering portion (26) of the pedestal (24) and the outer peripheral surface of the centering portion (65) of the mandrel (61) are parallel to the axis of the mandrel (60). The parts (65) and (26) are parallel.

The mandrel (60) is assembled at room temperature (T ₁ ). The mandrel ring (35) is externally fitted to the main body (62) from the convex part (63) side of the mandrel (61), and the convex part (63) is inserted into the concave part (25) of the base (24). (66) is screwed into the female thread portion (27) to fix the mandrel (61) to the base (24). At this time, the centering part (65) of the mandrel (61) and the centering part (26) of the pedestal (24) are assembled in parallel so that the axis of the mandrel (61) is aligned with the axis of the pedestal (24). Combined with high accuracy. That is, by providing the centering portion (65) (26) in which the outer peripheral surface of the convex portion (63) of the mandrel (61) and the inner peripheral surface of the concave portion (25) of the base (24) are parallel, Rather than attaching the mandrel (61) only by screwing the (66) and the female thread part (27), it is attached and fixed in a state where the center is aligned with high accuracy, and thus the uneven thickness of the extruded material is suppressed. . The mandrel ring (35) is sandwiched between the tip surface of the pedestal (24) and the head (64) of the mandrel (61) and is disposed at a predetermined position in the axial direction.

Even if the assembly is completed above the mandrel (60), at room temperature (T ₁₎ is the outer peripheral surface (62a) and the inner peripheral surface of the mandrel ring (35) of the main body portion of the mandrel (61) (62) (35a ) Is present in the gap (S ₁ ). In the present embodiment, the size of the gap (S ₁ ) is constant in the axial direction.

When assembling the mandrel (61) and the mandrel ring (35) at room temperature (T ₁ ), it is easy to fit the mandrel ring (35) to the mandrel (61) because of the gap (S ₁ ). is there. Furthermore, when the mandrel (61) is fixed to the pedestal (24) and the mandrel ring (35) is suppressed by the head (64), the main body (62) of the mandrel (61) generates a tensile force in the extrusion direction, The mandrel ring (35) generates a compressive force in the extrusion direction.

When the die temperature rises, the mandrel (61) and the mandrel ring (35) expand according to their respective thermal expansion coefficients (α ₁ ) (α ₂ ), and compressive force is generated in the main body (62) of the mandrel (61). In the mandrel ring (35), a circumferential tensile force is generated. And since the outer diameter expansion amount of the main-body part (62) of the mandrel (61) exceeds the inner diameter expansion amount of the mandrel ring (35), the clearance (S ₁ ) decreases, and as shown in FIG. When S ₁ ) disappears, the mandrel ring (35) is fixed to the main body (62) of the mandrel (61).

Since the head (64) of the mandrel (61) of this embodiment is integrated with the main body (62), the position of the head (64) is changed with the thermal expansion in the axial direction of the main body (62). Retreat downstream. When the die temperature rises, the dimensional expansion of the main body (62) exceeds the dimensional expansion of the mandrel ring (35) due to the difference in thermal expansion coefficient between the mandrel (61) and the mandrel ring (35). ) Tightening force changes in the direction of weakening. Even if the die temperature rises, as shown in FIG. 14B, as long as both ends of the mandrel ring (35) are in contact with the tip surface of the base (24) and the head (64) of the mandrel (61), The tightening force is good. In order to make use of the tightening force by the head (64) at the die temperature (T ₂ ) at the time of extrusion, it is necessary to apply a strong tightening force exceeding the amount of loosening due to temperature rise at normal temperature (T ₁ ). At normal temperature (T ₁ ), the length (L ₁ ) of the main body (62) of the mandrel (61) is set slightly shorter than the length (L ₂ ) of the mandrel ring (35), and the mandrel (61 ), The length (L ₃ ) of the centering part (65) is set to be shorter than the length (L ₄ ) of the centering part (26) of the base (24), so that both ends of the mandrel ring (35) The mandrel ring is adjusted by finely adjusting the position of the mandrel (61) by contacting the tip of the pedestal (24) and the head (64) of the mandrel (61) and tightening the male screw (66) and female screw (27). Adjust the tightening force applied to (35). In addition, since the downstream portion of the main body (62) is tapered and continues to the centering portion (65), the mandrel (61) can be smoothly moved upstream by tightening the screws. Is called. Then, when assembling the mandrel (60) at room temperature (T ₁ ), the tightening force on the mandrel ring (35) is appropriately adjusted according to the tightening of the screw, and the temperature rises to the die temperature (T ₂ ) during extrusion. Even if the tightening force is loosened, the head (64) is kept in contact with the mandrel ring (35).

In the structure in which the mandrel is detachably attached to the base portion of the die, the mandrel can be replaced and maintenance can be performed more easily. Further, in such a structure, since the mandrel ring can be fitted from the upstream side of the mandrel, when one or both of the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are inclined with respect to the axis line, The degree of freedom in designing the taper angle is higher than that of a mandrel (first to third embodiments) having a mandrel integrated with the base portion. For example, as shown in FIG. 17A, a mandrel formed by a tapered surface in which the outer peripheral surface (72a) of the mandrel (72) and the inner peripheral surface (75a) of the mandrel ring (75) are inclined outward toward the downstream side. 70), the upstream side where the outer diameter of the main body portion (72) is minimized is inserted into the downstream side where the inner diameter of the mandrel ring (75) is maximized. For this reason, even if the taper angle (θ ₁ ) of the outer peripheral surface (72a) of the mandrel (72) and the taper angle (θ ₂ ) of the inner peripheral surface (75a) of the mandrel ring (75) are set large, the mandrel (72) Since the assembly of the mandrel ring (75) is possible, the degree of freedom in designing the taper angles (θ ₁ ) (θ ₂ ) is high. As shown in FIG. 17B, the mandrel (70) has no gap (S ₁ ) at the die temperature (T ₂ ) during extrusion, and the outer peripheral surface (72a) of the main body (72) and the mandrel ring (75) The inner peripheral surface (75a) comes into contact with each other, and a contact surface (79) having an inclination angle (θ ₃ ) corresponding to the taper angle (θ ₁ ) (θ ₂ ) is formed. As described in the second embodiment, the contact surface that is inclined outward toward the downstream side has an effect of increasing the fixing stability of the mandrel ring in the axial direction. Therefore, in a structure in which the taper angle (θ ₁ ) (θ ₂ ) is not limited by whether assembly is possible or not, the axis line is set by setting the dimensions of the mandrel and the mandrel ring so that the inclination angle (θ ₃ ) of the contact surface is increased. The fixing stability of the mandrel ring in the direction can be improved.

  Furthermore, if the head (nut) is removed from the mandrel as in the first to third embodiments, the mandrel ring can be fitted from either the upstream side or the downstream side of the mandrel, so mandrel design is free. The degree becomes higher.

  The extrusion die of the present invention can be applied not only to the extrusion of a hollow material having a closed hollow portion, but also to the extrusion of a semi-hollow material having a part of the hollow portion opened.

  Moreover, as long as the material shape | molded using the extrusion die of this invention is a metal, it will not be limited at all, and aluminum, copper, iron, and these alloys can be illustrated.

  The extrusion die of the present invention can be used for producing various extruded materials having a hollow portion or a semi-hollow portion.

1 ... Extruded material
10 ... Porthole Dice
11 ... Female
20 ... Male mold (extrusion die)
21 ... Dice base
30, 40, 50, 60, 70 ... mandrels
32, 52, 72 ... mandrel
32a, 52a, 72a ... outer peripheral surface
35, 45, 75, 80, 82, 84, 86 ... Mandrel ring
81a… Upstream end face of substrate
81b ... Downstream end face of substrate
35a, 45a, 75a, 81c ... Inner peripheral surface
39a, 49a ... Base material
39b, 49b ... Alkali-resistant coating
36… Bearing part

Claims (7)

A mandrel that molds the inner surface of the extruded material has a mandrel and a mandrel ring fitted over the mandrel;
The mandrel ring is formed by forming a hard alkali-resistant coating on at least the outer peripheral surface of a base material made of a material having a smaller coefficient of thermal expansion than the mandrel,
The outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are in a state where the mandrel ring is externally fitted to the mandrel, there is a gap between them at room temperature, and at the die temperature during extrusion, at least in the axial direction of the mandrel An extrusion die characterized in that it is set so that there is no gap and the two come into contact with each other.   The extrusion die according to claim 1, wherein the mandrel ring is formed with an alkali-resistant coating only on the outer peripheral surface and the inner peripheral surface of the base material. When the clearance (X _T2 ) between the mandrel and the mandrel ring at the die temperature (T ₂ ) at the time of extrusion is expressed by the following formula in the portion where the gap at the normal temperature (T ₁ ) is the minimum, the normal temperature (T ₁ The outer diameter (A _T1 ) of the mandrel and the inner diameter (B _T1 ) of the mandrel ring at the time are set so that the interference (X _T2 ) is 0 to 0.3%. The extrusion die described.
X _T2 = {[A _T1 × (T ₂ −T ₁ ) × α ₁ + A _T1 ] / [B _T1 × (T ₂ −T ₁ ) × α ₂ + B _T1 ] −1} × 100
Where α ₁ : coefficient of thermal expansion of the material constituting the mandrel
α ₂ : coefficient of thermal expansion of the material constituting the base material of the mandrel ring (α ₁ > α ₂ )
T ₁ : normal temperature
T ₂ : Die temperature during extrusion (> T ₁ )
A _T1 : Outer diameter of the mandrel at normal temperature (T ₁ )
B _T1 : Inner diameter of mandrel ring at normal temperature (T ₁ ) (> A _T1 ) At the die temperature (T ₂ ) at the time of extrusion, the outer peripheral surface of the mandrel and the inner peripheral surface of the mandrel ring are in contact with each other because there is no gap in at least a part of the mandrel in the axial direction. The extrusion die according to any one of claims 1 to 3, wherein the extrusion die is set so as to have an inclined surface that is inclined outward toward the downstream side of extrusion with respect to the axis. In the state where the mandrel ring is externally fitted to the mandrel, there is a gap narrowing at the downstream side of the extrusion and widening at the upstream side between the two at normal temperature (T ₁ ), and at the die temperature (T ₂ ) at the time of extrusion. The extrusion die according to any one of claims 1 to 3, wherein an outer peripheral surface of the mandrel and an inner peripheral surface of the mandrel ring are formed so that the gap is eliminated at least on the downstream side.   The extrusion die according to claim 1, wherein the mandrel protrudes from a base portion of the die, and the mandrel is detachably attached to the base portion. Using the extrusion die according to any one of claims 1 to 6, extrusion is performed at a temperature at which there is no gap in at least part of the axial direction between the mandrel and the mandrel ring, and alkali cleaning is performed in the die maintenance after extrusion. An extrusion method characterized by the above.

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