Method for manufacturing mold for molding tire and mold for molding tire

Abstract

A vent hole of a mold for molding a tire is formed by suppressing bending deformation of a wire in a casting mold. By using a relational expression among a length of a wire in a casting space, a diameter of the wire, a contact angle of the wire with respect to a molten metal, and a bent amount of the wire by casting acquired by experiments, the contact angle of the wire at which the bent amount of the wire is within an allowable range is calculated from conditions of an actual length and the diameter of the wire. On the basis of the calculated contact angle of the wire, the wire is disposed in the casting space. By pouring the molten metal into the casting space, a cast metal with the wire cast-in in the casting space is cast. A vent hole is formed by withdrawing the wire.

Claims

1. A method for manufacturing a mold for molding a tire, comprising the steps of: pouring a molten metal into a casting space of a casting mold in which a wire is disposed; casting a cast metal of the mold for molding a tire with the wire cast-in in the casting space; and forming a vent hole by withdrawing the wire from the cast metal; the method further comprising the steps of: calculating a contact angle of the wire at which a bent amount of the wire is within an allowable range from conditions of an actual length and a diameter of the wire by using a relational expression indicating a relation among a length of the wire in the casting space, a diameter of the wire, the contact angle of the wire with respect to the molten metal, and the bent amount of the wire by casting, which is acquired by experiments in advance; and disposing the wire in the casting space on the basis of the calculated contact angle of the wire.

2. The method for manufacturing a mold for molding a tire according to claim 1, wherein the step of disposing the wire has the step of disposing the wire in the casting space by setting the contact angle of the wire to 90.

3. The method for manufacturing a mold for molding a tire according to claim 1, further comprising the step of calculating a condition of a thickness of a mold releasing agent capable of withdrawing the wire from the conditions of the actual length and the diameter of the wire by using a relational expression indicating a relation among the length of the wire in the casting space, the diameter of the wire, and the thickness of the mold releasing agent applied on the wire, which is acquired by experiments in advance and defines a condition capable of withdrawing the wire from the cast metal, wherein the step of disposing the wire has the step of disposing the wire satisfying the calculated condition of the thickness of the mold releasing agent in the casting space.

4. The method for manufacturing a mold for molding a tire according to claim 1, further comprising the step of calculating conditions of the length and the number of wires capable of preventing occurrence of a hydrogen gas defect from the conditions of an actual hydrogen content of the molten metal, the weight of the cast metal, the diameter of the wire, and the thickness of mold releasing agent by using a relational expression indicating a relation among the hydrogen content of the molten metal, the weight of the cast metal, the thickness of the mold releasing agent applied on the wire, the length of the wire in the casting space, the diameter of the wire, and the number of wires disposed in the casting space, which is acquired by experiments in advance and defines a condition capable of preventing occurrence of the hydrogen gas defect, wherein the step of disposing the wire has the step of disposing the wire in the casting space on the basis of the calculated conditions of the length and the number of the wires.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIGS. 1A to 1D are sectional views illustrating a manufacturing procedure of a mold for molding a tire of a first embodiment of the present invention.

(2) FIGS. 2A to 2D are sectional views illustrating a forming process of a vent hole by a wire.

(3) FIG. 3 is a table illustrating compositions of an alloy used for a mold.

(4) FIG. 4 is a table illustrating results of a casting experiment of the mold in the first embodiment.

(5) FIG. 5 indicates graphs comparing an actually measured value and a predicted value of a bent amount.

(6) FIGS. 6A and 6B are views illustrating how to dispose the wire in a second embodiment.

(7) FIGS. 7A to 7D are views for explaining withdrawal of the wire.

(8) FIG. 8 is a table illustrating results of a withdrawal experiment of the wire in a third embodiment.

(9) FIG. 9 indicates graphs comparing T/(DL) and a withdrawal success rate.

(10) FIGS. 10A to 10F are views for explaining occurrence of a hydrogen gas defect.

(11) FIG. 11 is a table illustrating results of the casting experiment in a fourth embodiment.

DESCRIPTION OF EMBODIMENTS

(12) An embodiment of a method for manufacturing a mold for molding a tire (hereinafter referred to simply as a mold) and a mold manufactured by this manufacturing method of the present invention will be described by referring to the attached drawings.

(13) The mold of each embodiment which will be described below is used for molding of a tire in vulcanization of the tire and molds at least a tread portion of the tire. Moreover, the mold is a split mold split into a plurality of parts in a tire circumferential direction of a tire to be molded and is split by a predetermined split angle around an axis (rotating axis) of the tire. In a vulcanizing machine, a plurality of molds is arranged annularly around the tire (unvulcanized tire), and the tread portion of the tire is molded into a predetermined shape by the plurality of molds.

First Embodiment

(14) FIGS. 1A to 1D are sectional views illustrating a manufacturing procedure of a mold 1 of a first embodiment, and FIG. 1A illustrates a casting mold 10 when seen from a side. FIG. 1B is a sectional view of the casting mold 10 when seen from an X1 direction of FIG. 1A, and FIG. 1C and FIG. 1D are sectional views of the mold 1 (cast metal 2) corresponding to FIG. 1A. In FIGS. 1A, 1B, and 1C, a portion (product portion) which becomes a product of the mold 1 is indicated by a two-dot chain line. An arrow M illustrated in FIG. 1A indicates a moving direction of a surface (schematically indicated by a dot line) of a molten metal 3 in the casting mold 10.

(15) The casting mold 10 includes a main mold 11 for molding the cast metal 2 of the mold 1, a molding flask 12 accommodating the main mold 11, and a stoke 13 for storing the molten metal 3 as illustrated. The main mold 11 is disposed so as to stand upright on a side of the cast metal 2. A casting space 14 for casting the cast metal 2 is formed in the casting mold 10 by the main mold 11 and the molding flask 12. A linear wire 20 is disposed in the casting space 14.

(16) The main mold 11 has a molding surface 11A of the cast metal 2 and is formed of a plaster. The wire 20 is a linear member (a spring steel wire, for example) for forming a vent hole 4 in the mold 1 and disposed at a plurality of spots in the casting space 14 corresponding to a position of the vent hole 4. Before assembling of the casting mold 10 (see FIGS. 1A and 1B), a base end portion of the wire 20 is inserted into a hole formed in the main mold 11 so that a plurality of wires 20 is mounted on the main mold 11 so as to protrude from the molding surface 11A. In that state, the casting mold 10 is assembled, and the cast metal 2 of the mold 1 is cast.

(17) During casting of the mold 1 (cast metal 2), an alloy is molten, and the molten metal 3 of the alloy is cast in the casting mold 10 (casting space 14). As a result, the molten metal 3 is poured into the casting space 14 of the casting mold 10 in which the wire 20 is disposed. Subsequently, the molten metal 3 is solidified in the casting space 14, and the cast metal 2 (alloy cast metal) of the mold 1 with the wire 20 cast-in is cast. After the cast metal 2 is cast by the casting mold 10 (see FIG. 1C), the cast metal 2 is taken out of the casting mold 10, the plurality of wires 20 is withdrawn from the cast metal 2, and a plurality of vent holes 4 is formed in the cast metal 2. After that, the cast metal 2 is machined, and the mold 1 to be used for molding of a tire is manufactured (see FIG. 1D). The vent holes 4 are formed from a surface for molding the tire of the mold 1 to a rear surface of the mold 1 and penetrate the mold 1.

(18) FIGS. 2A to 2D are sectional views illustrating a forming process of the vent hole 4 by the wire 20.

(19) As illustrated, a base end portion 21 of the wire 20 is fixed to the casting mold 10 (main mold 11), and the wire 20 is mounted on the casting mold 10 (see FIG. 2A). As a result, the wire 20 is supported by the casting mold 10 in a state similar to cantilever. Moreover, the wire 20 is made of a material having a melting point higher than a temperature of the molten metal 3 and has a mold releasing agent 22 applied on a surface thereof. The mold releasing agent 22 is an agent for allowing the wire 20 to be withdrawn from the cast metal 2 easily and prevents bonding between the cast metal 2 and the wire 20 during casting. A sectional shape of the wire 20 is circular, and the mold releasing agent 22 is uniformly applied on the whole of the wire 20.

(20) Here, during casting of the mold 1, the wire 20 is bent by a pressure P (see FIG. 2B) received from the molten metal 3, and bending deformation occurs in the wire 20 in some cases (see FIG. 2C). This pressure P is caused by an interfacial tension of the molten metal 3 and a surface film (oxidation film or the like) formed on the molten metal 3 and acts on the wire 20 with contact between the molten metal 3 and the wire 20. Moreover, with movement of the surface of the molten metal 3, the wire 20 is bent by the pressure P, and the molten metal 3 is solidified in a state in which the wire 20 is deformed. In this case, by withdrawing the wire 20 from the cast metal 2, the bent vent hole 4 is formed (see FIG. 2D).

(21) A bent amount W of the wire 20 (see FIG. 2C) is a function of a length L of the wire 20 in the casting space 14 (see FIG. 2A) and a diameter D of the wire 20 in the casting space 14 similarly to a bending expression of cantilever. Moreover, the bent amount W is a function of a contact angle of the wire 20 with respect to the molten metal 3 and the length L of the wire 20 and also depends on a property (interfacial tension, strength of the surface film and the like) of the molten metal 3. In the first embodiment, an expression indicating relation of a plurality of those variables is acquired by experiments, and the bent amount W of the wire 20 is quantitatively predicted, for example. On the basis of the result, conditions of the wire 20 capable of suppressing the bending deformation are set.

(22) Note that the bent amount W of the wire 20 is bending at a tip end portion 23 of the wire 20 and corresponds to a displacement distance of the tip end portion 23 caused by casting of the cast metal 2. That is, the bent amount W is a distance for which the tip end portion 23 is displaced after casting of the cast metal 2 on the basis of the tip end portion 23 before the molten metal 3 is poured. Moreover, the contact angle of the wire 20 (see FIG. 2A) is an angle formed by the surface of the molten metal 3 and the wire 20 when the molten metal 3 is brought into contact with the wire 20. That is, the contact angle is an angle formed by the surface of the molten metal 3 and the wire 20 before the wire 20 enters the molten metal 3 (before the wire 20 is bent).

(23) In the experiment, only a type of the alloy (molten metal 3), the length L of the wire 20, the diameter D of the wire 20, and the contact angle of the wire 20 were changed, and the cast metal 2 of the mold 1 is cast. The wire 20 is made of a spring steel wire (SUP-3) specified by Japanese Industrial Standards (JIS). The mold releasing agent 22 of the wire 20 was a mixed product of an acrylic resin and boron nitride (BN) (powder with average grain size of 10 m) (acrylic resin: 29%, BN: 71%), and it was applied on the wire 20 with a predetermined thickness. The main mold 11 was made of non-foaming plaster (by Noritake Co., Ltd., product name: G-6).

(24) The alloy was three types of aluminum alloy (AC4C, AC7A, and AC2B) for casting specified by JIS. During casting, a combination of the aforementioned three conditions (L, D, ) relating to the wire 20 was changed in various ways, while the other casting conditions were set the same. After the cast metal 2 of the mold 1 is cast by each alloy, the bent amount W of the wire 20 by casting of the mold 1 (cast metal 2) was measured.

(25) FIG. 3 is a table illustrating compositions of the alloy used for the mold 1 and also shows a material of the wire 20 and the like.

(26) FIG. 4 is a table illustrating results of a casting experiment of the mold 1 (cast metal 2) in the first embodiment and shows experimental results for each alloy. Moreover, FIG. 4 is a table arranging experimental conditions (D, L, ), the bent amounts (actually measured values) W of the wire 20, and the bent amounts (predicted values) W of the wire 20.

(27) In the first embodiment, as illustrated in FIG. 4, data indicating a relation among the four values (D, L, , and W) relating to the wire 20 is obtained for each alloy by the casting experiment. Then, on the basis of the obtained data, a relational expression of the length L of the wire 20, the diameter D of the wire 20, the contact angle of the wire 20, and the bent amount W of the wire 20 is constructed for each alloy. The relational expression is acquired by multivariate analysis (multiple regression analysis) assuming that the bent amount W of the wire 20 is an objective variable and the length L, the diameter D, and the contact angle are explanatory variables, for example. Here, the relational expression was created by using a product of a square of the diameter D and the length L as the explanatory variables.

(28) The relational expressions of the three alloys (AC4C, AC7A, and AC2B) are the following expression A to expression C.
[Formula 1]
W=(0.254017D.sup.20.676083D+0.452459)Lsin(90)ExpressionA (AC4C)
W=(0.352801D.sup.20.939004D+0.628416)Lsin(90)ExpressionB (AC7A)
W=(0.239904D.sup.20.638522D+0.427323)Lsin(90)ExpressionC (AC2B)

(29) These relational expressions are empirical expressions indicating a relation among the plurality of variables (W, D, L, and ) acquired by the experiments and also are prediction expressions predicting the bent amount W of the wire 20. By calculating the bent amount W from the length L, the diameter D, and the contact angle on the basis of the relational expression corresponding to the alloy of the mold 1, the bent amount W occurring during casting is predicted. The bent amount (predicted value) W illustrated in FIG. 4 is a value calculated by the expression A to the expression C.

(30) FIG. 5 indicates graphs comparing the actually measured value (lateral axis) and the predicted value (vertical axis) of the bent amount W and illustrates correlation between the actually measured value and the predicted value for each alloy.

(31) As illustrated, the predicted values well match the actually measured values, and the bent amount W of the wire 20 can be predicted by the relational expression with accuracy.

(32) At a stage in which the mold 1 is to be cast, the conditions of the length L of the wire 20, the diameter D of the wire 20, and the contact angle of the wire 20 under which the bent amount W of the wire 20 is within an allowable range are calculated (obtained) on the basis of the relational expression acquired by the experiments in advance, for example. Alternatively, on the basis of the relational expression, the condition of the contact angle of the wire 20 under which the bent amount W of the wire 20 is within the allowable range is calculated from the length L and the diameter D of the wire 20 actually used for casting of the mold 1. After that, the wire 20 (see FIGS. 2A to 2D) is disposed in the casting space 14 in accordance with the calculated conditions of the wire 20 so as to satisfy the conditions.

(33) Here, the contact angle of the wire 20 at which the bent amount W of the wire 20 is within the allowable range is calculated from the conditions of the actual length L and the diameter D of the wire 20 by using the relational expression acquired by the experiment in advance. Moreover, on the basis of the calculated contact angle of the wire 20, the wire 20 is disposed in the casting space 14. Specifically, on the basis of the relational expression, the length L of the wire 20, the diameter D of the wire 20, and the allowable range of the bent amount W, the contact angle of the wire 20 at which the bent amount W of the wire 20 is within the allowable range is calculated. The allowable range of the bent amount W is determined in advance in response to the condition required for the vent hole 4. In response to the allowable range, the contact angle (the condition of the contact angle ) is calculated from the relational expression, the length L, and the diameter D. Subsequently, the wire 20 with the diameter D is mounted on the casting mold 10 (main mold 11) in the state with the length L. At that time, the wire 20 is disposed in the casting space 14 in accordance with the calculated contact angle of the wire 20 so as to satisfy the condition of the contact angle . As a result, the wire 20 is disposed under the set condition, the casting mold 10 is assembled, and the cast metal 2 of the mold 1 is cast by the alloy of the relational expression. After that, by withdrawing the wire 20 from the cast metal 2, the vent hole 4 is formed, and the mold 1 having the vent hole 4 is manufactured.

(34) By disposing the wire 20 in the casting mold 10 as described above, the bent amount W of the wire 20 is within the allowable range and thus, bending of the vent hole 4 is suppressed. Therefore, bending deformation of the wire 20 is suppressed during casting of the mold 1 (cast metal 2), and the vent hole 4 of the mold 1 can be formed with accuracy. Moreover, since the vent hole 4 can be brought close to a straight shape, clogging of the vent hole 4 can be solved easily by an elongated tool.

Second Embodiment

(35) The aforementioned relational expressions (expression A to expression C) include a term of sin (90). Thus, if the contact angle of the wire 20 is 90, regardless of the conditions of the length L and the diameter D of the wire 20, the bent amount W of the wire 20 is zero. Paying attention to this characteristic, in a second embodiment, the contact angle of the wire 20 is set to 90, and the wire 20 is disposed in the casting space 14.

(36) FIGS. 6A and 6B are views illustrating how to dispose the wire 20 in a second embodiment and showing a section of the casting mold 10. Moreover, FIG. 6B is a sectional view of the casting mold 10 when seen from an X2 direction in FIG. 6A. In FIGS. 6A and 6B, a portion which becomes a product of the mold 1 (product portion) is indicated by a two-dot chain line. An arrow M illustrated in FIGS. 6A and 6B indicates the moving direction of the surface (schematically illustrated by a dot line) of the molten metal 3 in the casting mold 10.

(37) In the second embodiment, the main mold 11 is disposed horizontally in a lower part of the cast metal 2. The surface of the molten metal 3 moves upward from the main mold 11 in the casting space 14. By disposing the plurality of wires 20 so as to protrude upward from the main mold 11, the contact angle of the wire 20 is set to 90. As a result, since the wire 20 is disposed along a direction of the pressure P of the molten metal 3, it becomes difficult for the wire 20 to bend by the pressure P, and bending deformation of the wire 20 is suppressed. As a result, since the bent amount W of the wire 20 becomes much smaller, bending of the vent hole 4 can be reliably suppressed. Moreover, accuracy of the vent hole 4 can be further improved, and the vent hole 4 can be made thinner than before.

(38) As described above, if the contact angle can be set to 90, it is preferable that the contact angle is set to 90 and the wire 20 is disposed in the casting space 14. The term 90 in relation with the contact angle of the wire 20 refers to a predetermined angle range around 90 capable of suppressing bending deformation of the wire 20. That is, the wire 20 is disposed in the casting space 14 in a state in which the contact angle is approximately 90 (90). Here, the contact angle is an angle within a range of 80 to 100. However, in order to suppress bending deformation of the wire 20 more reliably, the contact angle is preferably set to an angle within a range of 85 to 95.

(39) As described above, the mold 1 is the split mold split into the plurality of parts in the tire circumferential direction, and the vent hole 4 is formed at a plurality of spots of the mold 1. In the second embodiment, by disposing the wires 20 along a center line CL (see FIG. 6B) of the mold 1, the plurality of vent holes 4 is formed along the center line CL. The center line CL of the mold 1 is a center line at a center position of the mold 1 in the tire circumferential direction, and the mold 1 is split by the center line CL into halves between split surfaces. All the vent holes 4 in the mold 1 are formed along the center line CL. Moreover, by disposing the wires 20 in parallel with the center line CL, all the vent holes 4 are formed in parallel with the center line CL.

Third Embodiment

(40) In a third embodiment, in addition to each of the aforementioned embodiments, a thickness of the mold releasing agent 22 required for withdrawing the wire 20 from the cast metal 2 is predicted, and a condition for the thickness of the mold releasing agent 22 is set. As a result, while bending deformation of the wire 20 is suppressed, the wire 20 is reliably withdrawn from the cast metal 2.

(41) FIGS. 7A to 7D are views for explaining withdrawal of the wire 20.

(42) As illustrated, after the molten metal 3 is contracted by solidification in the casting mold 10, the cast metal 2 is contracted by cooling (see FIGS. 7A to 7C). With such contraction, a pressure R (see FIG. 7C) is applied to the wire 20, and a frictional force between the wire 20 and the cast metal 2 becomes larger. When the wire 20 is to be withdrawn from the cast metal 2 (see FIG. 7D), a withdrawal resistance force J is applied to the wire 20 by the pressure R and the frictional force. At that time, if the withdrawal resistance force J is smaller than the strength (breaking strengthsectional area) of the wire 20, the wire 20 is withdrawn from the cast metal 2. On the other hand, if the withdrawal resistance force J is at the strength of the wire 20 or more, the wire 20 is broken and remains in the cast metal 2.

(43) Here, the pressure R received by the wire 20 is in proportion to the diameter D of the wire 20, a thickness T of the mold releasing agent 22, and a solidification/cooling contraction rate of the alloy (characteristic value of the alloy). Moreover, the withdrawal resistance force J is in proportion to the pressure R, an area of an outer periphery of the wire 20 (in proportion to diameter Dlength L), and a frictional coefficient (characteristic value of the wire 20 and the alloy) between the wire 20 and the cast metal 2. The strength of the wire 20 is in proportion to a sectional area (in proportion to a square of diameter D) of the wire 20, and the breaking strength of the wire 20 (characteristic value of the wire 20). Therefore, whether or not the wire 20 can be withdrawn from the cast metal 2 is estimated from the length L of the wire 20, the diameter D of the wire 20, the thickness T of the mold releasing agent 22, a wire characteristic, and an alloy characteristic.

(44) In the third embodiment, an expression indicating the relation among the plurality of variables is acquired by experiments, and the thickness T of the mold releasing agent capable of withdrawing the wire 20 is quantitatively predicted. On the basis of the result, the condition of the thickness T of the mold releasing agent 22 is set. In the experiment, only the type of the alloy, the diameter D of the wire 20, the thickness T of the mold releasing agent 22, and the length L of the wire 20 were changed, while the other casting conditions were set the same. Moreover, the alloy, the wire 20, the mold releasing agent 22, and the main mold 11 are made of a material similar to that of the first embodiment (see FIG. 3). Such an experiment was conducted that, after casting was performed under various conditions by the three types of alloys (AC4C, AC7A, and AC2B), the wire 20 was withdrawn from the cast metal 2. Moreover, under each condition, the plurality of wires 20 was withdrawn from the cast metal 2, and a withdrawal success rate was acquired.

(45) FIG. 8 is a table illustrating results of a withdrawal experiment of the wire 20 in the third embodiment and shows experimental results for each alloy. Moreover, FIG. 8 is a table arranging experimental conditions (D, T, L), T/(DL), and withdrawal success rates.

(46) FIG. 9 indicates graphs comparing T/(DL) (lateral axis) and the withdrawal success rate (vertical axis).

(47) In the third embodiment, as illustrated in FIG. 8, data indicating a relation among the three values (D, T, and L) and the withdrawal success rate is obtained for each alloy by the experiment. Subsequently, on the basis of the obtained data, a relational expression (conditional expression) of the length L of the wire 20, the diameter D of the wire 20, and the thickness T of the mold releasing agent 22 applied on the wire 20, which defines conditions capable of withdrawing the wire 20 from the cast metal 2, is constructed for each alloy. Here, a value of T/(DL) is calculated from the obtained data and a lower limit value F (constant) of T/(DL) at which the withdrawal success rate is 100% is obtained.

(48) As a result, as a relational expression (expression D), (TF(DL)) is obtained. In the example illustrated in FIG. 8 and FIG. 9, the lower limit value F is 0.000245 (AC4C) and 0.000321 (AC7A and AC2B). This relational expression is an empirical expression indicating a relation among the plurality of variables (T, D, and L) acquired by the experiments and also is a prediction expression predicting the thickness T of the mold releasing agent 22 capable of withdrawing the wire 20 from the cast metal 2. By calculating the thickness T of the mold releasing agent 22 from the length L and the diameter D of the wire 20 on the basis of the relational expression corresponding to the alloy of the mold 1, the required thickness T (lower limit value of the thickness T) is predicted.

(49) At a stage in which the mold 1 is to be cast, the condition of the thickness T of the mold releasing agent 22 capable of withdrawing the wire 20 is calculated (obtained) from the conditions of the actual length L of the wire 20 and the diameter D of the wire 20 by using the relational expression acquired by the experiment in advance. Moreover, in accordance with the calculated condition of the thickness T of the mold releasing agent 22, the wire 20 satisfying the condition is disposed in the casting space 14. For example, if the thickness T is at a predetermined value or more, the wire 20 having the mold releasing agent 22 satisfying the condition is disposed. By constituting as above, the wire 20 can be reliably withdrawn from the cast metal 2. If the material of the mold releasing agent 22 or the wire 20 is changed, the relational expression is created similarly to the above, and the condition of the thickness T of the mold releasing agent 22 is calculated.

Fourth Embodiment

(50) In a fourth embodiment, in addition to each of the aforementioned embodiments, whether or not a hydrogen gas defect (hereinafter referred to as gas defect) occurs in the mold 1 (cast metal 2) is predicted from an organic matter amount of the mold releasing agent 22 and an initial hydrogen amount of the molten metal 3. On the basis of the result, a condition that can prevent occurrence of the gas defect is set.

(51) FIGS. 10A to 10F are views for explaining occurrence of a gas defect K.

(52) The mold releasing agent 22 contains an organic matter in general. As illustrated, as the organic matter of the mold releasing agent 22 is burned and decomposed by heat during casting, a gas G is generated in the molten metal 3 (see FIG. 10B). Since oxygen in the gas G is easily bound to metal or carbon of the molten metal 3, oxygen is separated from the molten metal 3 and floated as an oxide or a gas (carbon monoxide, carbon dioxide) (see FIG. 10C). On the other hand, hydrogen in the gas G is easily absorbed by the molten metal 3 and is melted in the molten metal 3 to a predetermined solubility. During solidification of the molten metal 3, a hydrogen gas is generated in the molten metal 3 with a quick drop of the solubility, and the gas defect K occurs in the cast metal 2 in some cases (see FIGS. 10D and 10E). If the gas defect K appears on a surface of the mold 1 or in an inner surface of the vent hole 4, the gas defect K becomes a casting defect (see FIG. 10F).

(53) Here, assume that a hydrogen content (initial hydrogen amount) of the molten metal 3 during being poured into the casting space 14 is Hm and a hydrogen increase amount increasing in the molten metal 3 by the mold releasing agent 20 is Hp. Units of Hm and Hp are (cc/unit weight of alloy) (here, cc/100 g). If a sum of Hm and Hp (hydrogen total amount Hs) is not less than a threshold value specific to the alloy, the gas defect K occurs. After degasification treatment is applied to the molten metal 3 before being poured, a sample sampled from the molten metal 3 is analyzed so that Hm is obtained. Moreover, by an actual casting experiment, Hp and the hydrogen total amount Hs of the cast metal 2 are obtained.

(54) In the fourth embodiment, the mold 1 (cast metal 2) is cast under various conditions by experiments so as to obtain data of Hm, Hs, and Hp and to examine presence of the gas defect Kin the cast metal 2. In the experiment, the type of the alloy, the diameter D of the wire 20, the thickness T of the mold releasing agent 22, and the length L of the wire 20 were changed. Moreover, the alloy, the wire 20, the mold releasing agent 22, and the main mold 11 are made of a material similar to that of the first embodiment (see FIG. 3). A predetermined number of (one, here) wires 20 are disposed in the casting space 14, and the cast metal 2 (length: 120 mm, height: 50 mm, and thickness: 20 mm) was cast by the three types of alloys (AC4C, AC7A, and AC2B).

(55) FIG. 11 is a table illustrating results of a casting experiment in the fourth embodiment and shows experimental results for each alloy. Moreover, FIG. 11 is a table arranging experimental conditions (D, T, and L), a volume V of the mold releasing agent 22, an amount of hydrogen (Hm, Hs, Hp, and Hn), and presence of the gas defect K.

(56) The volume V of the mold releasing agent 22 is a volume of the mold releasing agent 22 applied on the one wire 20 and is calculated from the diameter D of the wire 20, the thickness T of the mold releasing agent 22, and the length L of the wire 20. A hydrogen absorption amount Hn is a hydrogen absorption amount of the cast metal 2 per unit volume (1 mm.sup.3, here) of the mold releasing agent 22 and is calculated from the hydrogen increase amount Hp, a weight Q of the cast metal 2, the volume V of the mold releasing agent 22, and the number N (total number) of the wires 20 disposed in the casting space 14.

(57) As illustrated in FIG. 11, the hydrogen absorption amount Hn changes depending on the alloy, and averages of the hydrogen absorption amount Hn are 0.1429 (AC4C), 0.2795 (AC7A), and 0.1729 (AC2B). A threshold value of the hydrogen total amount Hs at which the gas defect K occurs may be almost a constant value, which is 0.4 (AC4C, AC7A, and AC2B). Therefore, if the hydrogen total amount Hs is smaller than 0.4, it is predicted that the gas defect K does not occur in the cast metal 2. On the other hand, if the hydrogen total amount Hs is at 0.4 or more, it is predicted that the gas defect K occurs in the cast metal 2. In the fourth embodiment, on the basis of the hydrogen total amount Hs of the cast metal 2 and the threshold value (0.4), a relational expression (expression E) relating to occurrence of the gas defect K is acquired, and it is predicted whether or not the gas defect K occurs.
[Formula 2]
0.4>Hm+L{(T+D/2).sup.2(D/2).sup.2}NY/{10Q}Y={AC4C:0.1429,AC7A:0.2795,AC2B:0.1729}ExpressionE

(58) The hydrogen total amount Hs is a sum of the hydrogen content Hm of the molten metal 3 and the hydrogen increase amount Hp. Moreover, as illustrated in the relational expression, the hydrogen increase amount Hp is calculated from the length L of the wire 20, the thickness T of the mold releasing agent 22, the diameter D of the wire 20, the number N of the wires 20, the constant for each alloy (corresponding to the average of Hn), and the weight Q (kg) of the cast metal 2. This relational expression is an empirical expression indicating the relation among the plurality of variables (Hm, L, T, D, N, and Q) acquired by the experiments and also is a prediction expression predicting presence of occurrence of the gas defect K. On the basis of the relational expression corresponding to the alloy of the mold 1, by comparing the hydrogen total amount Hs calculated by the plurality of variables and the threshold value (0.4), presence of occurrence of the gas defect K is predicted.

(59) As described above, in the fourth embodiment, data indicating a relation among the four values (Hm, L, T, D, N, and Q) and presence of the gas defect K is obtained for each alloy by experiments. Subsequently, on the basis of the obtained data, data relating to the relational expression is obtained. Moreover, on the basis of the obtained data, a relational expression (conditional expression) of the hydrogen content Hm, the weight Q of the cast metal, the thickness T of the mold releasing agent 22, the length L of the wire 20, the diameter D of the wire 20, and the number N of the wires 20, which defines a condition capable of preventing occurrence of the gas defect K, is constructed for each alloy.

(60) At a stage in which the mold 1 is to be cast, by using the relational expression acquired by the experiment in advance, the conditions of the length L of the wire 20 and the number N of the wires 20, capable of preventing occurrence of the gas defect K are calculated (obtained) from the conditions of the actual hydrogen content Hm, the weight Q, the diameter D, and the thickness T. Moreover, on the basis of the calculated conditions of the length L and the number N of the wires 20, the wire 20 is disposed in the casting space 14 so as to satisfy the conditions. If (LN) is smaller than a predetermined value, for example, the length L and the number N are determined so as to satisfy the conditions. By constituting as above, occurrence of the gas defect K can be suppressed. Note that if the material of the alloy or the mold releasing agent 22 is changed, the relational expression is created similarly to the above, and occurrence of the gas defect K is predicted.

(61) (Manufacture Test of Mold 1)

(62) In order to confirm the effects of the present invention, a test of manufacturing the mold 1 by the manufacturing method described above was conducted. Test conditions are as follows:

(63) Cast metal 2: ring shape (inner diameter (600 mm), outer diameter (750 mm), height (300 mm), weight (350 kg))

(64) Alloy: AC4C, hydrogen content Hm (0.2 cc/100 g)

(65) Wire 20: diameter D (1.2 mm), length L (65 mm), number N (1200)

(66) Mold releasing agent 22: mixed product of acrylic resin and BN (see FIG. 3)

(67) Contact angle of wire 20: 0 to 30

(68) On the basis of the relational expression (expression A), the bent amount W of the wire 20 is calculated to be 0.39 to 0.45 mm within the allowable range. In the cast metal 2 in which the wire 20 is disposed under the aforementioned condition, the bent amount W (actually measured value) of the wire 20 was within the allowable range, and bending deformation of the wire 20 was able to be suppressed.

(69) Moreover, on the basis of the relational expression (expression D), the thickness T of the mold releasing agent 22 capable of withdrawing the wire 20 is 0.019 mm or more. In order to satisfy this condition, the thickness T of the mold releasing agent 22 was set to 0.02 mm. As a result, the withdrawal success rate of the wire 20 was 100%.

(70) If the thickness T is 0.02 mm, on the basis of the relational expression (expression E), the number N of the wires 20 capable of preventing occurrence of the gas defect K is less than 1982. Actually, occurrence of the gas defect K was able to be suppressed at all the 1200 spots.

(71) Subsequently, the mold 1 was manufactured under a test condition illustrated below:

(72) Cast metal 2: a fan shape obtained by splitting a ring shape by a split angle 45 (weight (80 kg))

(73) Alloy: AC7A, hydrogen content Hm (0.15 cc/100 g)

(74) Wire 20: diameter D (0.6 mm), length L (65 mm), number N (130)

(75) Mold releasing agent 22: mixed product of acrylic resin and BN (see FIG. 3), thickness T (0.015 mm)

(76) In a comparative example, the contact angle of the wire 20 was 30, and the bent amount W of the wire 20 was 10 to 12 mm. On the other hand, in an example, the contact angle of the wire 20 was set to 85. As a result, the bent amount W of the wire 20 was 0 to 1 mm, and the bent amount W was drastically made small. In the comparative example and the example, the withdrawal success rate of the wire 20 was 100%, and occurrence of the gas defect K was able to be suppressed.

REFERENCE SIGNS LIST

(77) 1 mold 2 cast metal 3 molten metal 4 vent hole 10 casting mold 11 main mold 12 molding flask 13 stoke 14 casting space 20 wire 21 base end portion 22 mold releasing agent 23 tip end portion