JPWO2007135995A1 - Manufacturing method of salt core for casting and salt core for casting - Google Patents

Abstract

In the formation of the salt core (2) when the die casting method is used, first, a molten salt is prepared by heating and melting a mixed salt containing at least a potassium salt and a sodium salt. Next, the temperature of this molten metal is lowered to a semi-solid state (solid-liquid coexistence), and the hot water in a semi-solid state is injected into a salt core mold by high pressure and solidified. Do by taking out.

Description

  The present invention relates to a method for producing a water-soluble casting salt core and a casting salt core.

  For example, as is well known, casting of aluminum die casting or the like is a technique for casting a structure having a desired shape by injecting a molten aluminum alloy into a mold at high speed and high pressure. In such casting, for example, a core is used when a casting having a hollow structure such as a water jacket for water cooling such as a cylinder block of an internal combustion engine is formed. The core used in such a case is susceptible to a large impact due to collision of the molten metal injected from the gate at a high speed, and the casting pressure is large until the solidification is completed. Required. In addition, the core is removed from the casting after casting. However, in the case of a casting having a complicated internal structure, the core is removed when a sand core solidified with a general phenol resin is used. It is not easy. On the other hand, there are water-soluble salt cores that can be removed by dissolving with high-temperature water or the like (Reference 1: JP-A-48-039696, Reference 2: JP-A-50-136225, Document 3: JP-A-52-010803).

The salt core as described above uses, for example, a mixed salt composed of sodium carbonate (Na ₂ CO ₃ ), potassium chloride (KCl), sodium chloride (NaCl), and the like, and is molded by melting them to have a high pressure resistance. In addition to obtaining strength, workability and stability in casting are improved.

  However, when salt is melted and cast to form a salt core, shrinkage, microporosity, fine thermal cracks, etc. occur in the salt core due to volume changes such as solidification shrinkage that occur during the solidification process. It was not easy to mold accurately according to the mold. Further, depending on the composition of each component, the melting point may be 700 ° C. or higher, which is not suitable for melt molding. As described above, the conventional technique has a problem that a salt core cannot be easily manufactured by casting using a molten salt.

  The present invention has been made to solve the above problems, and a casting salt core having a water-solubility comprising a cast product of a salt formed by melting a salt such as sodium or potassium, The object is to make it easier to manufacture.

  The method for producing a casting salt core according to the present invention is a first method in which a mixed salt containing at least a potassium salt and a sodium salt is heated to form a solid-liquid coexisting melt in which a solid phase and a liquid phase coexist. And a second step of putting the molten metal in a solid-liquid coexisting state into a core molding die and a third step of solidifying the molten metal inside the die to form a casting salt core. Is. Therefore, when the mold is filled, a part of the molten metal is solidified.

  Further, the casting salt core according to the present invention forms a melt in a solid-liquid coexistence state in which a solid phase and a liquid phase coexist by heating a mixed salt containing at least a potassium salt and a sodium salt. The molten metal in the coexistence state is put into a mold for core forming, and the molten metal is solidified inside the mold. This casting salt core is, for example, a core for forming a water jacket for water cooling of an engine cylinder.

  According to the present invention, since the casting is performed using the molten metal coexisting with the solid and liquid, a salt core for casting having a water-solubility comprising a salt casting formed by melting a salt such as sodium or potassium. However, it becomes easier to manufacture.

FIG. 1 is a perspective view of a cylinder block when cast using the salt core for casting according to the present invention. FIG. 2 is a metallographic microscope (optical microscope) photograph showing the state of the solidified structure of the salt core 2. FIG. 3 is a characteristic diagram showing the temperature dependence of the solid phase ratio of a semi-solid state molten metal. FIG. 4 is a scanning electron micrograph of a solidified structure when a mixed salt having a composition containing a large amount of chloride is melt-molded and solidified without stirring. FIG. 5 is a scanning electron micrograph of a solidified structure when a mixed salt having a composition containing a large amount of carbonate is melt-molded and solidified without stirring. FIG. 6A is a graph showing the bending strength of the bending test pieces of sample numbers 1 to 9. FIG. 6B is a graph showing the bending strength of the bending test pieces of sample numbers 10 to 12. FIG. 6C is a graph showing the bending strength of the bending test pieces of sample numbers 13 to 17. FIG. 7A is a graph showing the bending strength of the bending test pieces of sample numbers 18-23. FIG. 7B is a graph showing the bending strength of the bending test pieces of sample numbers 24-27. FIG. 8 is a characteristic diagram (state diagram) showing the relationship between the cation ratio of potassium ions and the anion ratio of carbonate ions and the liquidus temperature. FIG. 9A is a configuration diagram illustrating a state of a test piece used for bending strength measurement. FIG. 9B is a cross-sectional view showing a part of a test piece used for bending strength measurement. FIG. 10 is an explanatory diagram for explaining the bending strength measurement. FIG. 11 is a photograph for explaining the measurement points of the pressure in the cavity during the injection molding of the salt core. FIG. 12 is an explanatory view showing the measurement result of the pressure in the cavity during the injection molding of the salt core. FIG. 13 is a perspective view of another cylinder block when cast using the salt core for casting according to the present invention. FIG. 14 is a photograph of the salt core 1302 shown in FIG.

  Embodiments of the present invention will be described below with reference to the drawings. First, the usage form of the salt core for casting which concerns on the Example of this invention is demonstrated using FIG. FIG. 1 is a perspective view of a cylinder block in the case of casting using a casting salt core according to the present invention, which is drawn in a partially broken state. In FIG. 1, what is shown by the code | symbol 1 is the cylinder block for engines which consists of an aluminum alloy cast using the salt core 2 as a salt core for casting which concerns on this invention. The cylinder block 1 is a part of a water-cooled four-cycle four-cylinder engine for a motorcycle, and is formed into a predetermined shape by a die casting method.

  A cylinder block 1 shown in FIG. 1 is integrally formed with a cylinder body 4 having four cylinder bores 3 and cylinder bores 3 and an upper crankcase 5 extending downward from the lower end of the cylinder body 4. A lower crankcase (not shown) is attached to the lower end of the upper crankcase 5 and a crankshaft (not shown) is rotatably supported through a bearing together with the lower crankcase.

  The cylinder body 4 is of a so-called closed deck type, and a water jacket 6 is formed inside using a salt core 2. The water jacket 6 includes a cooling water passage forming portion 7, a cooling water inlet 8, a main cooling water passage 9, and a communication passage 10. The cooling water passage forming portion 7 projects from one side of the cylinder body 4 and extends in the direction in which the cylinder bores 3 are arranged. The cooling water inlet 8 is formed in the cooling water passage forming portion 7. The main cooling water passage 9 communicates with a cooling water distribution passage (not shown) formed inside the cooling water passage forming portion 7 and is formed so as to cover the periphery of all the cylinder bores 3. Further, the communication passage 10 extends upward from the main cooling water passage 9 in FIG. 1 and opens to a mating surface 4 a with a cylinder head (not shown) at the upper end of the cylinder body 4.

  The above-described water jacket 6 supplies the cooling water flowing from the cooling water inlet 8 to the main cooling water passage 9 around the cylinder bore through the cooling water distribution passage, and further supplies this cooling water from the main cooling water passage 9 to the communication passage 10. It is comprised so that it may guide to the cooling water path in a cylinder head (not shown) through. By forming the water jacket 6 in this way, the cylinder body 4 has a ceiling wall of the cylinder body 4 except that the communication path 10 of the water jacket 6 is opened at the upper mating surface 4a to which the cylinder head is connected. It will be covered with (wall which forms the mating surface 4a), and becomes a closed deck type structure.

  The salt core 2 for forming the water jacket 6 is formed in a shape in which each part of the water jacket 6 is integrally connected. In FIG. 1, the cylinder body 4 is drawn in a partially broken state so that the shape of the salt core 2 (the shape of the water jacket 6) can be easily understood.

  The salt core (salt core for casting) 2 according to this embodiment uses a plurality of salts such as sodium carbonate, sodium chloride, and potassium chloride, and is in the state of solid-liquid coexistence such as semi-solidification, for example, die casting method. Thus, the shape of the water jacket 6 is formed. The salt core 2 heats a mixed salt containing at least a potassium salt and a sodium salt to form a melt in a solid-liquid coexistence state in which a solid phase and a liquid phase coexist, and this molten mold is used as a mold for core molding. The molten metal is solidified inside the mold and molded. The method for producing the salt core 2 will be described in detail below.

  The salt core 2 can be formed by using other casting methods such as a gravity casting method in addition to the die casting method. In the formation of the salt core 2 in the case of using the die casting method, first, a molten metal is made by heating and melting a mixture of a plurality of salts described later. Next, the temperature of the molten metal is lowered to a semi-solid state (solid-liquid coexistence), and the molten metal in a semi-solid state is injected into a salt core mold by high pressure to be solidified and taken out from the mold after solidification. By doing.

  As shown in FIG. 1, the salt core 2 includes a passage forming portion 2a that forms a cooling water inlet 8 and a cooling water distribution passage, an annular portion 2b that surrounds the four cylinder bores 3, and an annular portion. A plurality of convex portions 2c protruding upward from 2b are formed integrally. The communication path 10 of the water jacket 6 is formed by these convex portions 2c. As is well known in the art, the salt core 2 is supported at a predetermined position in a mold (not shown) by a skirting board (not shown) at the time of casting, and is melted by hot water or steam after casting. To remove.

  In order to remove the salt core 2 after casting, it can be performed by immersing the cylinder block 1 in a dissolution tank (not shown) in which a solution composed of hydrochloric acid and warm water is stored. By immersing the cylinder block 1 in the solution, the passage forming portion 2a in the salt core 2 and the convex portion 2c exposed on the mating surface 4a come into contact with the solution and dissolve. This dissolved portion gradually expands and finally all the sites are dissolved. In such a core removal step, hot water or steam may be sprayed with pressure from the hole in order to promote dissolution of the salt core 2 remaining in the water jacket 6. The salt core 2 can also insert a baseboard instead of the convex part 2c in the site | part in which the convex part 2c is formed.

  Further, when hydrochloric acid is used in the step of removing the salt core 2 from the cylinder block 1 that is a casting, since carbon dioxide gas is foamed, a stirring action by this foaming can be obtained, and dissolution can be effectively promoted. Moreover, since the salt core 2 contains potassium carbonate or sodium carbonate, it will exhibit alkalinity when dissolved in water. Thus, in the alkaline state, there is a problem that the cylinder block 1 which is an aluminum casting is corroded. Also against this problem, corrosion of the cylinder block can be prevented by adding hydrochloric acid and controlling the pH to be close to 7.

Next, the manufacturing method of the salt core 2 is demonstrated in detail. First, a case will be described in which the salt core 2 is manufactured by pouring (injecting) the molten metal into the mold without pouring (injecting) the molten metal at a high pressure as in the die casting method (gravity casting method). The salt core 2 in the present embodiment is first mixed with sodium carbonate, potassium carbonate, sodium chloride, and potassium chloride, and heated until they are melted to prepare a molten salt of mixed salt. For example, the molar component ratio XK ⁺ (= [K ⁺ ] / ([Na ⁺ ] + [K ⁺ ]) × 100) of potassium ions in all cations is 33 mol%, and the molar components of carbonate ions in all anions When the above salt is mixed so that the ratio YCO ₃ ²⁻ (= [CO ₃ ²⁻ ] / ([CO ₃ ²⁻ ] + [Cl ⁻ ]) × 100) is 67 mol%, it dissolves at 647 ° C. . For example, the mixed salt described above may be placed in an alumina crucible and melted in an electric furnace.

  Next, when the temperature of the mixed salt accommodated in the crucible reached a liquidus temperature of 647 ° C. or higher, the crucible was taken out of the electric furnace and air-cooled. The cooling rate was 0.3 to 1.2 ° C. per second. At this time, the mixed salt in the crucible was stirred at a rotation speed of 3 revolutions per second with an alumina stirrer, and poured into a mold when the temperature of the molten salt of the mixed salt was 638 ° C. When the molten salt of the mixed salt is 638 ° C., it is in a semi-solid state where the solid phase and the liquid phase coexist. The molten metal in this state is solidified by putting it in a mold for a salt core, and taken out from the die after solidification. . In the above description, the mixed salt is heated to a liquid phase only, and then cooled to form a solid-liquid coexisting molten metal. However, the present invention is not limited to this. The mixed salt may be heated to a temperature at which it becomes semi-solidified to obtain a semi-solid state.

  The strength (bending strength) of the salt core 2 thus obtained was as high as 21.4 to 24.6 MPa. Moreover, the solidification structure of the salt core 2 was composed of fine crystal grains as can be seen from the metal micrograph of FIG. Further, as shown in FIG. 3, in the mixed salt having the above composition, the temperature range of solid-liquid coexistence is as large as about 60 ° C., and the temperature dependence of the solid phase rate is small in the range of the solid phase rate of 0 to 40%. Therefore, it is easy to obtain a molten salt of a mixed salt in a uniform solid-liquid coexistence state. Thus, according to the manufacturing method in the present embodiment, the salt core 2 can be manufactured without strict temperature control or isothermal holding. Depending on the composition ratio of each component of the mixed salt, the temperature range from the temperature at which the entire molten metal becomes a solid phase to the temperature at which the entire melt becomes a liquid phase, in other words, the temperature range in which the solid-liquid coexistence state is maintained changes.

  In the process of cooling the molten metal as described above, when the temperature of the molten metal becomes equal to or lower than the liquidus temperature (melting point), a plurality of solid phase particles are generated, and the plurality of solid phase particles are retained in the remaining liquid phase. It is in a dispersed state. At this time, a state in which the solid phase is more uniformly dispersed in the liquid phase can be obtained by stirring the melt in a semi-solid state. However, stirring is not necessary.

As an example, FIG. 4 shows that XK ⁺ (= [K ⁺ ] / ([Na ⁺ ] + [K ⁺ ]) × 100) is 0 mol%, YCO ₃ ²⁻ (= [CO ₃ ²⁻ ] / ([CO ₃ ^2- ] + [Cl ⁻ ]) × 100) shows a scanning electron microscope (SEM) photograph of a solidified structure when a mixed salt having a composition of 10 mol% is melt-molded and solidified without stirring. In this composition, the primary crystal is likely to grow in a dendritic form, so it is better to stir. As another example, FIG. 5 shows that XK ⁺ (= [K ⁺ ] / ([Na ⁺ ] + [K ⁺ ]) × 100) is 0 mol%, YCO ₃ ²⁻ (= [CO ₃ ²⁻ ]). ² shows an SEM photograph of a solidified structure when a mixed salt having a composition of / ([CO ₃ ²⁻ ] + [Cl ⁻ ]) × 100) is melt-molded and solidified without stirring. With this composition, a granular primary crystal is likely to be crystallized, so stirring may be omitted.

  As described above, stirring is not necessary, but stirring may be performed. This is because the temperature distribution in the mixed salt in the solid-liquid coexistence state can be lowered by stirring, and it becomes easy to obtain a mixed salt having a uniform solid phase ratio. In addition, the solid phase particles in the mixed salt in a solid-liquid coexisting state can be refined and spheroidized by stirring, so that moldability is improved. When molding a core with a high solid phase ratio, it is better to stir. In addition, when performing mechanical stirring, it is preferable to use ceramics having good corrosion resistance against molten salt as the stirring bar.

  When the core is molded from the semi-solid state with the above-mentioned characteristics, the amount of solidification shrinkage that occurs during the solidification process can be suppressed, so that the shrinkage nest, microporosity, and fine thermal cracks that occur in the salt core are suppressed. It becomes possible. Further, since the amount of coagulation shrinkage can be suppressed, it becomes possible to mold the mold as accurately as possible. When casting from a completely melted state as in the past, the amount of solidification shrinkage is large, so many shrinkage nests, microporosity and fine thermal cracks occur, but the amount of these generations can be suppressed by the semi-solidification method, For this reason, strength can be improved.

  In the melt molding method, since the amount of solidification shrinkage of the core to be molded is larger than the amount of shrinkage of the mold, when trying to form a cylindrical annular core such as a water jacket of a cylinder, Microporosity and fine thermal cracks may occur, and in some cases, the salt core may break in the mold. On the other hand, since the solidification shrinkage rate can be reduced by using the melt in a semi-solid state as described above, a cylindrical annular core such as a water jacket can be formed.

  In addition, in injection molding using a molten metal, so-called flushing that causes the molten metal to scatter from the mold parting surface occurs when injection is performed with a larger radiant output than the machine clamp strength. On the other hand, in the injection molding using the molten metal coexisting with the solid and liquid, the molten metal tip is immediately solidified, so that flushing does not occur even when the injection is performed with a larger output than the projected area of the mold cavity. For this reason, it becomes possible to apply a large injection pressure for replenishing the molten metal during solidification shrinkage of the molten metal, thereby crushing the cast hole. In addition, by using a molten metal in a solid-liquid coexisting state, casting can be performed at a temperature lower than that in a completely molten state, so that workability can be improved and the heat load on the mold can be reduced.

  Further, unlike a metal, a salt does not oxidize, and even when the above-described stirring is performed in the air, an oxide is not involved in the molten metal, and the molten metal can be easily stirred for a long time. Further, even when an annular shape is formed in a semi-solid state, an oxide film is not formed at the joint portion on the opposite side of the molten metal that is divided into two in the circumferential direction from the gate. Therefore, there is no separation at the joint after forming by cold shut.

  In order to obtain a solid-liquid coexistence state, the solid-liquid coexistence state is set by cooling from the melted state to the semi-solidified region, but is not limited thereto. For example, the solid phase mixed salt may be heated to a semi-molten region to be in a solid-liquid coexistence state. Further, a solid powdery salt (mixed salt) may be added to the molten salt so as to be in a solid-liquid coexistence state. Further, a molten salt may be added to a preheated solid salt (mixed salt) to make it coexist in a solid-liquid state.

By the way, in the above description, the molar component ratio XK ⁺ (= [K ⁺ ] / ([Na ⁺ ] + [K ⁺ ]) × 100) of potassium ions in all cations is 33 mol%, carbonate ions in all anions. Sodium carbonate, potassium carbonate, sodium chloride, so that the molar component ratio of YCO ₃ ²⁻ (= [CO ₃ ²⁻ ] / ([CO ₃ ²⁻ ] + [Cl ⁻ ]) × 100) is 67 mol%. However, the present invention is not limited to this case. For example, even when the compositions shown in Tables 1 and 2 below are used, casting using a semi-solid molten metal is possible. In any case, the mixed salt is formed only from potassium ions, sodium ions, chlorine ions, and carbonate ions.

  By the way, in Table 1, the measurement result (maximum bending load) of the bending strength of the produced test piece is also shown, and in Table 2, the measurement result (maximum bending strength) of the bending strength of the produced test piece is also shown. Yes. Tables 1 and 2 are the same except that the way of expressing the measurement results is changed. These bending load and bending strength states are shown as bar graphs in FIGS. 6A to 6C and FIGS. 7A and 7B. The concentration of each ion is measured by an analysis method established in the general rules for ion chromatograph analysis of JIS standard K0127.

FIG. 8 shows the relationship between the cation ratio of potassium ions and the anion ratio of carbonate ions and the melting temperature (liquidus temperature) (phase diagram of Na—K—Cl—CO ₃ system). 8, each composition shown in Table 1 is shown corresponding to the sample number. Further, in FIG. ^{8, K + 0mol%, CO} 3 2- 0mol% of the liquidus temperature of NaCl _{^{when, Na + 0mol%, CO 3}} 2- 0mol% of the liquidus temperature of the KCl in the case, K _{^{+ 0mol%, Cl - Na 2}} CO 3 of the liquidus temperature of the case of ^{0mol%, Na + 0mol%,} Cl - liquidus temperature of the of K ₂ CO ₃ when the 0 mol% is also shown. In FIG. 8, the eutectic line is indicated by a bold line.

By the way, as apparent from Tables 1 and 2, and FIGS. 6A to 6C, FIGS. 7A, 7B, and 8, XK ⁺ is ⁰ to 50 mol%, and YCO ₃ ²⁻ is 30 to 80 mol%. In this region, a high bending strength is obtained as a result of the bending test. In addition, particularly high bending strength is obtained in a region where XK ⁺ is ⁰ to 40 mol% and YCO ₃ ²⁻ is 50 to 70 mol%.

  Next, measurement of the bending strength will be described. For the measurement of the bending strength, a prismatic test piece having a predetermined size is prepared, a load is applied to the test piece, and the bending load is obtained from the maximum load required for the fracture. First, preparation of a test piece will be described. A rod-shaped test piece 901 as shown in FIGS. 9A and 9B is formed using a predetermined mold. The used mold is made of chrome molybdenum steel such as SCM440H, for example. Although FIG. 9A also shows the portion 902 of the hot water used for filling the mold with the semi-solid melt, the portion 902 is cut out in the measurement of the bending strength. 9A shows a side view, FIG. 9B shows a cross-sectional view at the position bb in FIG. 9A, and the dimensions shown in the drawing are design values in the mold.

  As shown in FIG. 10, the bending strength of the rod-shaped test piece 901 produced as described above is measured by first supporting two supports arranged with a gap of 50 mm at the center of the test piece 901. The test piece 901 is supported by the part 1001. In a state of being supported in this manner, a load is applied to the test piece 901 by two load portions 1002 having an interval of 10 mm at an intermediate position between the two support portions 1001. The load applied to the test piece 901 was gradually increased, and the load when the test piece 901 was broken was defined as the bending load shown in Table 1.

Here, the bending strength σ (MPa) can be obtained from the bending load P according to the formula “σ = 3LP / BH ² ”. In the above formula, H represents the length in the load direction in the cross section of the test piece, B represents the length perpendicular to the load direction in the cross section of the test piece, and L represents a load portion to which a load is applied from the support portion 1001 serving as a fulcrum. The interval is up to 1002. By the way, the test piece 901 is formed by pouring the molten metal coexisting with the solid and the liquid into the above mold, but it has no hot water and no sinkholes, and has a shape that completely matches the dimensions of the mold. It is hard to fall. For this reason, the bending strength is calculated by approximating that the cross-section of the test piece is rectangular, and H≈20 mm, B≈18 mm, and L = 20 mm. By making this approximation, the strength is estimated to be 0 to 20% lower than the actual strength. For example, a test piece fractured at a bending load of 1200 N is an ideal test piece having a bending strength of 10 MPa. It can be considered stronger.

  Next, the manufacturing method of the other salt core in the Example of this invention is demonstrated. Below, the case where the molten metal is filled in the mold (mold) under pressure to produce the salt core 2 will be described (die casting method). The crucible is a dense alumina crucible made of the same material as the Tamman tube. A predetermined amount of a mixed salt composed of sodium carbonate, potassium carbonate, sodium chloride, and potassium chloride is placed in the crucible, and the temperature is raised in a heating furnace. In the temperature increase, in order to protect the crucible, the temperature is gradually increased to the target temperature over about 14 hours.

  The target temperature is set to a value 10 to 30 ° C. higher than the liquidus temperature corresponding to the molar component ratio of the mixed salt, and is maintained at the temperature after reaching the target temperature. Moreover, the temperature of a metal mold | die and an injection sleeve shall be about 180-220 degreeC. The mold is preferably one that can be heated to a mold temperature of about 250 ° C. It is preferable that the casting injection pressure is as high as about 120 MPa, which can crush the casting cavity.

  Next, the molten salt of the mixed salt melted in the crucible is drawn up with a handle. However, before lifting, the handle is heated to about 500 to 600 ° C. by a heating means such as a burner. When the molten metal is pumped up from the crucible with the handle, the molten metal is gradually deprived of heat by the handle and the temperature becomes lower than the liquidus temperature, so that a solid-liquid coexistence state is obtained. At this time, the molten metal is shaken and stirred in the moving handle and the primary crystals are precipitated in a granular form. Thus, the molten salt of the mixed salt is in a solid-liquid coexistence state in the handle of the process of transporting and pouring the molten metal from the crucible to the injection sleeve.

  When the molten salt of the mixed salt that has become semi-solidified in this way is poured into the injection sleeve, the semi-solid state also proceeds in the sleeve, and subsequently injected into the cavity at high pressure. After filling the melt, continue to apply casting pressure into the mold. For example, a pressure of 120 MPa is applied into the mold at a pressure ratio of a hydraulic cylinder that advances the plunger. In this process, the plunger is advanced and the application of the pressure of 120 MPa is continued so as to replenish the coagulation contraction that occurs as the solidification progresses. The coagulation time is about 65 to 75 seconds. During the solidification process, while the solidification contraction can be replenished, the plunger continues to advance and the pressure of 120 MPa is continuously applied.

  As described above, the molten metal is filled into the mold under pressure and solidified, and then the solidified core is removed from the mold. It is advisable to put a push pin and a return pin in the fixed mold so that the material can be well separated from the fixed mold when the mold opens. The taken-out salt core is gradually cooled, and the cooled salt core may be accommodated in a dry container.

  An example of the production conditions and strength measurement results of the salt core produced by high-pressure injection of a molten salt of mixed salt in a semi-solid state coexisting with solid and liquid into a mold will be described.

The conditions are as follows.
(1) The test piece for which the strength measurement was performed was formed in a substantially rectangular parallelepiped shape as in FIGS. 9A and 9B.
(2) The molten metal is prepared by mixing sodium carbonate, potassium carbonate, sodium chloride, and potassium chloride and melting them, and the molar component ratio XK ⁺ (= [K ⁺ ] / ([Na ⁺ ] + [K ⁺ ]) × 100) is 30 mol%, and the molar component ratio of carbonate ions in all anions YCO ₃ ²⁻ (= [CO ₃ ²⁻ ] / ([CO ₃ ²⁻ ] + [Cl ⁻ ]) × 100) was adjusted to 54 mol%.
(3) The liquidus temperature of the mixed salt is 630 ° C.
(4) The mixed salt accommodated in the crucible was gradually heated and melted over 14 hours until the liquidus temperature exceeded 630 ° C., and the molten metal temperature was maintained at 640 to 660 ° C. The temperature control was performed automatically.
(5) Heat the handle to 500-600 ° C.
(6) The molten metal is pumped up with the handle and cooled to 630 ° or less in the handle. → Make it semi-solidified.
(7) The sleeve temperature and the mold temperature were 180 to 220 ° C.
(8) When the temperature of the molten salt of the mixed salt was 620 ° C. in the injection sleeve, this molten metal was injected into the mold at a high pressure like an injection curve described later. When the molten salt of the mixed salt is 620 ° C., it is in a semi-solid state where solid and liquid coexist.

  Here, when the pressure in the cavity is measured by the pressure applied to the push pins provided at two locations of the gate portion 1101 and the inner portion 1102 shown in FIG. 11, the injection curve of FIG. As shown in FIG. In FIG. 12, the solid line indicates the measurement result in the portion 1101, and the wavy line indicates the measurement result in the portion 1102. Further, the measured pressure was maintained at a substantially constant state of about 60 MPa from the start of injection to immediately before the end of solidification (about 5 seconds before) when the mold was opened, and rapidly decreased at the time of mold opening. Actually, the measured pressure drops little by little as shown in FIG. This is presumably because the salt core solidifies from the surface and the pressure is hardly transmitted. In addition, a state of directional solidification was shown in which the pressure on the inner side of the mold first dropped before the gate portion. As described above, a pressure of about 120 MPa was applied to the plunger, but a part of the molten metal solidified in a gel shape in the injection sleeve hindered the driving of the plunger and was actually added to the molten metal in the cavity. It is considered that the pressure was about 60 MPa.

  In the case of die casting of metal such as aluminum, the molten metal has good thermal conductivity and the solidification time is short. In many cases, the middle part solidifies before the end of the mold, and it is sufficient to reach the end of the mold. The molten metal may not be replenished. In contrast, molten salt is low in thermal conductivity and takes about three times as long as aluminum to solidify, so it is possible to continue applying almost constant pressure to the entire cavity until mold opening, as shown in FIG. It is. In this way, until the mold is opened, the same pressure is always applied to the cavity until the mold is opened, or the pressure applied to the cavity is gradually changed by the same change amount until the mold is opened. Applying pressure uniformly to the cavity is a condition for obtaining high strength.

  As a result of measuring the bending strength of the test piece manufactured as described above as described above, a high strength exceeding 40 MPa was obtained as shown in Tables 3 and 4 below. In general, salt cores manufactured by sintering after press molding are currently used have a bending strength of about 20 to 37 MPa (Reference 4: US Pat. No. 3,963,818). According to the present embodiment, higher bending strength is obtained. In addition, a salt core manufactured by sintering after press molding cannot have a complicated shape such as a water jacket, but according to this embodiment, a salt core having a complicated shape can be easily formed. Can be manufactured. In addition, since the salt core in this embodiment is formed by solidifying molten salt, the surface state of the mold is reflected in the surface state of the salt core, and a smooth surface is obtained. For this reason, in the casting using the salt core according to the present embodiment, the portion in contact with the salt core is formed in a state having high smoothness.

  In the above description, a mixed salt of sodium carbonate, potassium carbonate, sodium chloride, and potassium chloride is used. However, the present invention is not limited to this. For example, potassium carbonate, sodium chloride, and potassium chloride may be mixed, and sodium carbonate, sodium chloride, and potassium chloride may be mixed. Other salts such as sodium bromide, potassium bromide, sodium iodide, potassium iodide, calcium chloride, potassium nitrate, sodium nitrate, potassium sulfate, lithium sulfate, magnesium sulfate, sodium sulfate, barium carbonate, and calcium carbonate It may be mixed. Further, these may contain ceramics for reinforcement, other reinforcing agents, and the like.

  Next, another usage pattern of the casting salt core according to the embodiment of the present invention will be described with reference to FIGS. FIG. 13 is a perspective view of a cylinder block when the salt core for casting according to the present invention is used for casting. FIG. 13 is a partially broken view. In FIG. 13, what is indicated by reference numeral 1301 is an engine cylinder block made of an aluminum alloy cast using a salt core 1302 as a casting salt core according to the present invention. The salt core 1302 is manufactured in the same manner as the salt core 2 shown in FIG. This cylinder block 1301 is a part of a water-cooled four-cycle single-cylinder engine for a motorcycle, and is formed into a predetermined shape by a die casting method.

  A cylinder block 1301 shown in FIG. 13 includes a cylinder body 1304 having a cylinder bore 1303 and a cylinder bore 1303. Although not shown, a crankcase is attached to the lower portion of the cylinder body 1304, and the crankshaft is rotatably supported via a bearing.

  The cylinder body 1304 is of a so-called closed deck type, and a water jacket 1306 is formed inside using a salt core 1302. The water jacket 1306 includes a cooling water passage forming portion (not shown), a cooling water inlet (not shown), a main cooling water passage 1309, and a communication passage 1310. The cooling water passage forming portion projects from one side of the cylinder body 1304. The cooling water inlet is formed in the cooling water passage forming portion. The main cooling water passage 1309 communicates with a cooling water supply passage (not shown) formed inside the cooling water passage formation portion and is formed so as to cover the periphery of the cylinder bore 1303. Further, the communication passage 1310 extends upward from the main cooling water passage 1309 in FIG. 13 and opens to a mating surface 1304a with a cylinder head (not shown) at the upper end of the cylinder body 1304.

  The above-described water jacket 1306 supplies the cooling water flowing from the cooling water inlet (not shown) to the main cooling water passage 1309 around the cylinder bore through the cooling water supply passage, and this cooling water is further supplied to the main cooling water passage 1309. To the cooling water passage in the cylinder head (not shown) through the communication passage 1310. By forming the water jacket 1306 in this way, the cylinder body 1304 has a ceiling wall of the cylinder body 1304 except that the communication path 1310 of the water jacket 1306 is opened at the upper mating surface 1304a to which the cylinder head is connected. It will be covered with (the wall forming the mating surface 1304a) and will be a closed deck type configuration.

  The salt core 1302 for forming the water jacket 1306 is formed in a shape in which the respective parts of the water jacket 1306 are integrally connected as shown in the photograph of FIG. In FIG. 13, the cylinder body 1304 is depicted in a partially broken state so that the shape of the salt core 1302 (the shape of the water jacket 1306) can be easily understood. Reference numeral 1311 denotes a camshaft drive chain passage, and reference numeral 1312 denotes a chain tensioner mounting hole.

  The salt core 1302 shown in FIG. 13 (FIG. 14) uses a plurality of salts such as sodium carbonate, sodium chloride, and potassium chloride as in the case of the salt core 2 described above. The water jacket 1306 is formed in a shape by a die casting method in which casting is performed in a state. The salt core 1302 can be formed by using other casting methods such as a gravity casting method in addition to the die casting method. In the formation of the salt core 1302 when the die casting method is used, first, a molten metal is made by heating and melting a mixture composed of a plurality of salts described later. Next, the temperature of the molten metal is lowered to a semi-solid state (solid-liquid coexistence), and the molten metal in a semi-solid state is injected into a salt core mold by high pressure to be solidified and taken out from the mold after solidification. By doing.

  As shown in FIG. 13, the salt core 1302 includes a cooling water passage forming portion (not shown) that forms a cooling water inlet and a cooling water supply passage, an annular portion 1302b that surrounds the cylinder bore 1303, A plurality of convex portions 1302a projecting upward from the annular portion 1302b are integrally formed. A communication passage 1310 of the water jacket 1306 is formed by these convex portions 1302a. As is well known in the art, the salt core 1302 is supported at a predetermined position in a mold (not shown) by a skirting board (not shown in FIG. 13) at the time of casting. Dissolve with steam and remove.

  The salt core 1302 can be removed after casting by immersing the cylinder block 1301 in a dissolution tank (not shown) in which a solution made of hydrochloric acid and warm water is stored. By immersing the cylinder block 1301 in the solution, the cooling water inlet of the cooling water passage forming portion (not shown) in the salt core 1302 and the convex portion 1302a exposed on the mating surface 1304a come into contact with the solution. Dissolve. This dissolved portion gradually expands and finally all the sites are dissolved. In such a core removal step, hot water or steam may be blown from the hole with pressure in order to promote dissolution of the salt core 1302 remaining in the water jacket 1306. The salt core 1302 can also insert a baseboard instead of the convex part 1302a in the part in which the convex part 1302a is formed.

  As described above, according to the present invention, the annular salt core 1302 can be easily formed. 14 is an area protruding above the mating surface 1304a in FIG. Further, the overflow, gate, runner, and biscuit portions shown in the photograph of FIG. 14 are formed when the salt core 1302 is cast, but are deleted when the salt core 1302 is used for casting the cylinder block 1301. Is done.

  The present invention is suitably used as a core in casting of aluminum die casting or the like.

Claims (13)

A first step of heating a mixed salt containing at least a potassium salt and a sodium salt to form a melt in a solid-liquid coexistence state in which a solid phase and a liquid phase coexist;
A second step of putting the molten metal in a solid-liquid coexistence state into a mold for core molding;
And a third step of forming a casting salt core by solidifying the molten metal inside the mold. In the manufacturing method of the salt core for casting of Claim 1,
In the first step, the mixed salt is heated to form a liquid phase only, and then cooled to form the molten metal in a solid-liquid coexistence state. Production method. In the manufacturing method of the salt core for casting of Claim 1,
In the second step and the third step, the molten metal is filled into the mold under pressure and solidified to solidify the casting salt core. In the manufacturing method of the salt core for casting of Claim 3,
The method for producing a salt core for casting, wherein the pressure is uniformly applied until the mold is opened. In the manufacturing method of the salt core for casting of Claim 1,
The mixed salt is
Formed only from potassium, sodium, chloride, and carbonate ions,
A casting salt core characterized in that the molar component ratio of potassium ions in all cations is 50 mol% at the maximum, and the molar component ratio of carbonate ions in all anions is 30 to 80 mol%. Production method. In the manufacturing method of the salt core for casting of Claim 5,
The mixed salt has a molar component ratio of potassium ions in all cations of 40 mol% at maximum and a molar component ratio of carbonate ions in total anions of 50 to 70 mol%. For producing a salt core.   A mixed salt containing at least a potassium salt and a sodium salt is heated to form a solid-liquid coexisting molten metal in which a solid phase and a liquid phase coexist, and the solid-liquid coexisting molten metal is used as a mold for core molding. A salt core for casting, which is molded by solidifying the molten metal inside the mold. The salt core for casting according to claim 7,
The molten salt in a solid-liquid coexistence state is formed by heating the mixed salt to form a liquid phase only, and then cooling the mixed salt. The salt core for casting according to claim 7,
The casting salt core is formed by filling the molten metal with pressure into the mold and solidifying the molten salt core. The casting salt core according to claim 9,
The salt core for casting, wherein the pressure is uniformly applied until the mold is opened. The salt core for casting according to claim 7,
The mixed salt is
Formed only from potassium, sodium, chloride, and carbonate ions,
A casting salt core, wherein the molar component ratio of potassium ions in all cations is 50 mol% at the maximum, and the molar component ratio of carbonate ions in all anions is 30 to 80 mol%. The casting salt core according to claim 11,
The mixed salt has a molar component ratio of potassium ions in all cations of 40 mol% at maximum and a molar component ratio of carbonate ions in total anions of 50 to 70 mol%. Salt core. The salt core for casting according to claim 7,
The casting salt core is a core for forming a water jacket for water cooling of an engine cylinder.

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