WO2014156246A1 - Sand-mold molding method and sand-mold molding apparatus - Google Patents
Sand-mold molding method and sand-mold molding apparatus Download PDFInfo
- Publication number
- WO2014156246A1 WO2014156246A1 PCT/JP2014/051273 JP2014051273W WO2014156246A1 WO 2014156246 A1 WO2014156246 A1 WO 2014156246A1 JP 2014051273 W JP2014051273 W JP 2014051273W WO 2014156246 A1 WO2014156246 A1 WO 2014156246A1
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- WIPO (PCT)
- Prior art keywords
- mold
- sand
- cavity
- foamed
- gap
- Prior art date
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- 238000000034 method Methods 0.000 title claims description 22
- 238000000465 moulding Methods 0.000 title claims description 10
- 239000004576 sand Substances 0.000 claims abstract description 106
- 238000010438 heat treatment Methods 0.000 claims abstract description 21
- 239000011230 binding agent Substances 0.000 claims abstract description 11
- 238000005187 foaming Methods 0.000 claims description 13
- 238000003756 stirring Methods 0.000 claims description 4
- 238000010304 firing Methods 0.000 abstract description 5
- 229910052751 metal Inorganic materials 0.000 abstract description 4
- 239000002184 metal Substances 0.000 abstract description 4
- 238000007711 solidification Methods 0.000 abstract description 2
- 230000008023 solidification Effects 0.000 abstract description 2
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 21
- 239000006260 foam Substances 0.000 description 19
- 239000007789 gas Substances 0.000 description 18
- 238000001125 extrusion Methods 0.000 description 12
- NTHWMYGWWRZVTN-UHFFFAOYSA-N sodium silicate Chemical compound [Na+].[Na+].[O-][Si]([O-])=O NTHWMYGWWRZVTN-UHFFFAOYSA-N 0.000 description 9
- 235000019353 potassium silicate Nutrition 0.000 description 8
- 230000002950 deficient Effects 0.000 description 4
- 239000004094 surface-active agent Substances 0.000 description 4
- 238000005266 casting Methods 0.000 description 3
- 238000007599 discharging Methods 0.000 description 3
- 239000002245 particle Substances 0.000 description 3
- 239000003232 water-soluble binding agent Substances 0.000 description 3
- 238000007664 blowing Methods 0.000 description 2
- 239000000470 constituent Substances 0.000 description 2
- 239000010410 layer Substances 0.000 description 2
- 239000000203 mixture Substances 0.000 description 2
- 239000002344 surface layer Substances 0.000 description 2
- 239000004115 Sodium Silicate Substances 0.000 description 1
- 239000007864 aqueous solution Substances 0.000 description 1
- 230000001276 controlling effect Effects 0.000 description 1
- 230000007423 decrease Effects 0.000 description 1
- 230000008020 evaporation Effects 0.000 description 1
- 238000001704 evaporation Methods 0.000 description 1
- 230000001105 regulatory effect Effects 0.000 description 1
- 238000004904 shortening Methods 0.000 description 1
- 229910052911 sodium silicate Inorganic materials 0.000 description 1
- 229920005992 thermoplastic resin Polymers 0.000 description 1
Images
Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C7/00—Patterns; Manufacture thereof so far as not provided for in other classes
- B22C7/06—Core boxes
- B22C7/065—Venting means
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C15/00—Moulding machines characterised by the compacting mechanism; Accessories therefor
- B22C15/02—Compacting by pressing devices only
- B22C15/08—Compacting by pressing devices only involving pneumatic or hydraulic mechanisms
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C19/00—Components or accessories for moulding machines
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C9/00—Moulds or cores; Moulding processes
- B22C9/02—Sand moulds or like moulds for shaped castings
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C9/00—Moulds or cores; Moulding processes
- B22C9/12—Treating moulds or cores, e.g. drying, hardening
Definitions
- the present invention relates to a sand mold making method and a sand mold making apparatus for filling a mold with foamed sand and solidifying it to form a sand mold such as a sand core.
- collapsible sand cores When casting engine cylinder blocks, cylinder heads, etc., collapsible sand cores (sand molds) are used to form hollow parts such as water jackets and intake / exhaust ports.
- the sand core is formed into a predetermined shape by, for example, blowing shell sand coated with a thermoplastic resin into a mold with compressed air from a nozzle of a sand blowing device, filling the cavity, and heating and solidifying.
- a sand mold such as a core using foamed sand obtained by stirring and foaming water and a water-soluble binder together with an aggregate.
- foamed sand obtained by stirring and foaming water and a water-soluble binder together with an aggregate.
- the internal pressure of the cavity increases due to evaporation of moisture and thermal expansion of bubbles during the heating and curing (firing) process of the foam sand.
- a water-soluble binder and aggregate are accumulated on the surface layer portion to form a dense hardened layer having high strength, while a brittle portion having a low density is formed inside.
- the core made of foam sand is excellent in disintegration after casting and can be easily removed from the cast product while ensuring sufficient strength as a core during casting.
- Foamed sand generates water vapor and gas when heated and hardened in the mold, so it is necessary to discharge these to the outside of the mold cavity smoothly. Accordingly, a mold for foaming sand is provided with a slit or a passage for discharging water vapor and gas. Further, Patent Document 1 is not for foaming sand, but a gas vent hole is provided in the mold, and when the shell sand is fired in the mold cavity, the generated gas is discharged from the mold cavity. The point to do is described.
- the present invention has been made in view of the above points, and when heating and curing foam sand in a mold cavity, water vapor and gas are smoothly discharged from the cavity to shorten the curing time. With the goal.
- the present invention provides a sand mold molding method and a sand mold molding method in which a foamed sand obtained by stirring a binder together with an aggregate and foaming is filled in a cavity of a mold and heated and solidified to obtain a molded product.
- a foamed sand obtained by stirring a binder together with an aggregate and foaming is filled in a cavity of a mold and heated and solidified to obtain a molded product.
- the mold is clamped to form the cavity, and the cavity is filled with foamed sand, and then the mold is slightly opened to provide a gap between the molds while maintaining the cavity.
- a mold that forms a cavity by mold clamping a mold clamping apparatus that opens and closes the mold, a filling apparatus that fills the cavity with foamed sand that is stirred and foamed with an aggregate, and the cavity
- a heating device for heating the foamed sand inside The mold clamping device is characterized in that, after filling the cavity with foamed sand, the mold is slightly opened to form a gap between the molds while maintaining the cavity.
- the mold clamping device reduces a mold clamping force and forms a gap between the molds by a reaction force from the molds.
- the sand mold making method and apparatus of (1) and (4) when heating and curing the foamed sand in the cavity of the mold, a minute gap is provided between the molds so that water vapor and gas are transferred to the mold. Since it is smoothly discharged to the outside through the gaps between them, the curing time can be shortened. Even when the solidified binder accumulates in the passage for discharging water vapor and gas from the mold cavity, the water vapor and gas can be reliably discharged from the cavity to the outside by the gap between the molds. At this time, since the gap between the molds is sufficiently small and the shape and dimensions of the cavity are maintained, the dimensional accuracy of the molded product is not affected.
- the gap between the molds can be adjusted according to the reaction force from the mold.
- the sand mold making method and apparatus of (3) and (6) it is possible to perform a desired mold by optimizing the gap.
- the mold clamping device performs mold clamping of the mold by an air cylinder, and reduces the pressure of compressed air supplied to the air cylinder to reduce the clamping force.
- a sand mold making device performs mold clamping of the mold by an air cylinder, and reduces the pressure of compressed air supplied to the air cylinder to reduce the clamping force.
- a sand mold making apparatus 1 forms a sand core (sand mold) by solidifying foam sand, and includes a mold 2 that forms a cavity C, and a mold 2.
- the foamed sand S used in the present embodiment is a mixture of sand as an aggregate and water glass (sodium silicate), water-soluble inorganic binder containing water and a surfactant, and kneaded into a foamed state. It is.
- An image of the state of the particles constituting the foamed sand S is shown in FIG. 6A shows a state in which the bubbles 8 are adsorbed on the surface of the sand particles 7, and FIG. 6B shows a part of the bubbles 8 in an enlarged manner. As shown in FIG.
- the foam sand S forms a foam 8 by covering the surface of a water glass aqueous solution (water is indicated by reference numeral 10 and water glass is indicated by reference numeral 11) with a surfactant 9. 8 is adsorbed on the surface of the sand particles 7 through the surfactant 9 to be in a foamed state, and has an appropriate viscosity.
- the molar ratio of water glass to sand is 1.0 to 3.0
- the weight ratio is 0.4 to 3.0%
- the weight ratio of water is 1.5 to 5.0%
- the weight of the surfactant By setting the ratio to about 0.003 to 2.0%, foam sand S having an appropriate viscosity can be obtained.
- the mold 2 includes a fixed mold 12 and a movable mold 13 divided by a parting line P, and the fixed mold 12 and the movable mold 13 are clamped to form a cavity C.
- the fixed mold 12 is fixed to the fixed base 14.
- the movable mold 13 is fixed to a movable movable base 15 and moves together with the movable base 15 to open and close the mold 2.
- the fixed mold 12 and the movable mold 13 are heated to about 150 ° C. to 300 ° C. by a heating device H such as a heater, and the foam sand S filled in the cavity C is evaporated to solidify the foam sand S.
- the mold 2 may be provided with a discharge passage such as a slit 16 for discharging gas and water vapor to the outside when the foamed sand S is heated and hardened in the cavity C.
- a mold release device 17 is provided for each of the fixed mold 12 and the movable mold 13 of the mold 2.
- the mold release device 17 includes a plurality of extrusion pins 18 provided so as to be movable back and forth in the cavity C, an extrusion plate 19 connected to the bases of the plurality of extrusion pins 18, a fixed base 14 and a movable base 15.
- An extrusion spring 20 provided between the extrusion plate 19 and the extrusion plate 19 is provided. Then, the plurality of push pins 18 are pressed through the push plate 19 by the spring force of the push springs 20 so that the tips of the push pins 18 protrude into the cavity C.
- Retraction pins 21 whose front ends are opposed to each other are attached to the extrusion plates 19 on both sides.
- the filling device 3 kneads and stores foam sand S, a pressurizing mechanism 23 that pressurizes foam sand S in the sand tank 22, and filling that connects the sand tank 22 to the cavity C of the mold 2. And a mouth 24. Then, the sand tank 22 is set on the mold 2 which is closed and clamped by closing the fixed mold 12 and the movable mold 13, and the foaming sand S in the sand tank 22 is pressurized by the pressurizing mechanism 23, thereby filling the filling port 24. The foamed sand S is filled into the cavity C of the mold 2 via.
- the mold clamping device 4 switches the double-acting air cylinder 26 that drives the movable base 15, the air source 27 that supplies compressed air to the air cylinder 26, and the supply of compressed air from the air source 27 to the air cylinder 26.
- the switching valve 28 for moving the movable base 15 forward and backward, the pressure adjusting valve 29 for adjusting the pressure of the compressed air supplied to the air cylinder, and the pressure gauge 30 for detecting the pressure of the compressed air supplied to the air cylinder 26
- a control device 31 that controls the operation of the switching valve 28 and the pressure regulating valve 29.
- the control device 31 controls the switching valve 28, switches the supply of compressed air, and expands / contracts the actuating rod 26A of the double-acting air cylinder 26, thereby moving the movable mold 13 together with the movable base 15 to move the mold. 2 is opened and closed. Further, the mold clamping force is adjusted by operating the pressure adjustment valve 29 based on the pressure detected by the pressure gauge 30 during mold clamping and adjusting the pressure of the compressed air supplied to the air cylinder 26. Thereby, when foaming sand S is heated and hardened in the cavity C of the mold 2, if the clamping force by the air cylinder 26 is reduced, the pressure in the cavity C and the spring force of the extrusion spring 20 of the mold release device 17 are reduced.
- the movable mold 13 Due to the reaction force caused by the warp of the mold 2, the movable mold 13 is slightly retracted, and a minute gap L (see FIG. 2C) is formed in the parting line P between the fixed mold 12 and the movable mold 13. It is formed and this gap L can be adjusted.
- FIG. 2A the movable mold 13 is driven by the mold clamping device 4 to close the mold 2, the mold is clamped to form a cavity C, and the filling device 3 is set in the mold 2.
- the extrusion pin 18 of the mold release device 17 moves backward from the cavity C in conjunction with the mold clamping as described above.
- the pressurizing mechanism 23 of the filling device 3 is operated, and the foamed sand S in the sand tank 22 enters the cavity C of the mold 2 heated through the filling port 24.
- FIG. 2B shows a state where the filling of the foam sand S into the cavity C is completed.
- the foamed sand S filled in the cavity C of the mold 2 evaporates and hardens when heated.
- the process of heating and hardening the foamed sand C filled in the cavity C will be described with reference to FIG.
- the bubbles 8 of the foamed sand S expand due to heating, and the internal pressure of the cavity C rises.
- the bubbles 8 move along the inner wall of the cavity C of the mold 2 to the outside through a passage formed by the slit 16 or the like provided in the parting line P. Discharged.
- the water glass (binder) and the aggregate composing the foam sand S are pushed toward the inner wall side of the cavity C, and the density of the water glass and the aggregate near the inner wall of the cavity C is increased.
- the sand core W solidified in the cavity C is formed with a dense hardened layer 33 having a high density of water glass and aggregate on the surface layer portion in contact with the inner wall of the cavity C, and the internal density decreases.
- a fragile portion 34 that easily collapses is formed at the center.
- the water glass (binder) pushed to the inner wall side of the cavity C enters the passage made of the slit 16 and the like together with water vapor and gas and is discharged to the outside.
- the binder that has entered the passage is cured and fixed to the passage.
- the control device 31 of the mold clamping device 4 operates the pressure adjustment valve 29 based on the detected pressure of the pressure gauge 30, so that the air cylinder The supply pressure of compressed air to 26 is reduced by a predetermined pressure, and the clamping force is reduced.
- FIG. 2C the pressure in the cavity C increased by heating and hardening of the foamed sand S, the spring force of the extrusion spring 20 of the mold release device 17, and the warpage due to the warp of the mold 2.
- the movable mold 13 Due to the force, the movable mold 13 is slightly retracted, and a minute gap L is formed in the parting line P between the fixed mold 12 and the movable mold 13.
- the gas and water vapor generated during heating and hardening of the foamed sand S in the cavity C of the mold 2 are smoothly discharged to the outside through the minute gap L.
- solidification of the foamed sand S can be promoted, and the firing time can be shortened.
- the minute gap L is a slight gap that allows gas and water vapor to be smoothly discharged, and the amount of movement of the movable mold 13 is also small, so that the shape and dimensions of the cavity C are maintained. Does not affect the core shape and dimensional accuracy. Further, the movable mold 13 is slightly moved by the pressure in the cavity C, the spring force of the extrusion spring 20 of the mold release device 17, and the warping reaction force of the mold 2, so that the movable mold 13 is slightly moved from the fixed mold 12. Since the gap L is formed, a constant minute gap L can be secured regardless of the amount of binder deposited on the parting line P and the slit 16 between the molds 2. As a result, the gas and water vapor generated during the heating and curing of the foamed sand S can be reliably discharged to the outside, and a good molded product can be obtained by shortening the firing time.
- the control valve 31 is operated by the control device 31 to switch the supply of compressed air to the double-acting air cylinder 26, and the movable base 15 is moved together with the movable base 15. 13 is retracted, the mold 2 is opened, and the molded sand core is taken out. At this time, the tip of the retreat pin 21 of the mold release device 17 is separated in conjunction with the mold opening, the push plate 19 is moved by the spring force of the push spring 20, and the push pin 18 protrudes into the cavity C to make a mold. Release the sand core.
- the supply pressure is reduced to 0.15 MPa, 0.10 MPa, and 0.05 MPa against the supply pressure of 0.35 MPa of compressed air to the air cylinder 26 during mold clamping.
- the gaps L were 0.22 mm, 0.25 mm, and 0.36 mm on average, respectively.
- the molded product is 60% non-defective product and 40% defective product.
- the supply pressure is reduced to 0.10 MPa and the gap L is provided, the non-defective product is 80% and the defective product is 20%.
- the supply pressure is further reduced to 0.05 MPa and the gap L is increased, 100% good product is obtained.
- 100% good product is obtained.
- the supply pressure (clamping force) of the compressed air to the air cylinder 26 of the mold clamping device 4 is reduced, and the reaction force between the molds 2 causes the space between the fixed mold 12 and the movable mold 13.
- the predetermined gap L may be formed by directly controlling the movement amount of the movable mold 13.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Molds, Cores, And Manufacturing Methods Thereof (AREA)
- Casting Devices For Molds (AREA)
Abstract
[Problem] To smoothly discharge from the cavity of a metal mold the moisture vapor and gas produced during heating and solidifying of foamed sand, when obtaining a molded part by filling the cavity with the foamed sand and heating and solidifying the foamed sand. [Solution] A metal mold (2) is clamped to form a cavity (C), and the cavity (C) is filled with foamed sand (S). When the foamed sand (S) is heated and solidified, the clamping force is reduced and a slight opening (L) is formed in the metal mold (2) while maintaining the cavity (C). The gas and moisture vapor produced during heating and solidification of the foamed sand (S) are smoothly discharged from inside the cavity (C) through the opening (L) to the exterior, thereby allowing the firing time of the foamed sand (S) to be shortened. Even when solidified binder has collected in a slit (16), the gas and moisture vapor can be effectively discharged to the exterior from inside the cavity (C) through the opening (L).
Description
本発明は、金型に発泡砂を充填し固化して砂中子等の砂型を造型する砂型造型方法及び砂型造型装置に関するものである。
The present invention relates to a sand mold making method and a sand mold making apparatus for filling a mold with foamed sand and solidifying it to form a sand mold such as a sand core.
エンジンのシリンダブロックやシリンヘッド等を鋳造する際、ウォータジャケットや吸排気ポート等の中空部を形成するために崩壊性の砂中子(砂型)が用いられる。砂中子は、例えば、熱可塑性樹脂で被覆したシェル砂を砂吹込み装置のノズルから圧縮空気によって金型に吹込み、キャビティ内に充填し、加熱して固めることによって所定の形状に形成される。
When casting engine cylinder blocks, cylinder heads, etc., collapsible sand cores (sand molds) are used to form hollow parts such as water jackets and intake / exhaust ports. The sand core is formed into a predetermined shape by, for example, blowing shell sand coated with a thermoplastic resin into a mold with compressed air from a nozzle of a sand blowing device, filling the cavity, and heating and solidifying. The
これに対して、水、水溶性バインダーを骨材と共に撹拌して発泡させた発泡砂を用いて中子等の砂型の造型を行う技術がある。このように、発泡砂を金型のキャビティに充填して造型を行う場合、発泡砂の加熱、硬化(焼成)の過程で水分の蒸発及び気泡の熱膨張により、キャビティの内圧が高まるため、造型品は、表層部に水溶性バインダー及び骨材が集積して緻密で強度の高い硬化層が形成される一方、内部に密度が低く脆い脆弱部が形成される。このため、発泡砂により造型された中子は、鋳造時には、中子として充分な強度を確保しつつ、鋳造後は、崩壊性に優れ、鋳造品から容易に取除くことができる。
On the other hand, there is a technique for forming a sand mold such as a core using foamed sand obtained by stirring and foaming water and a water-soluble binder together with an aggregate. In this way, when molding is performed by filling the mold cavity with foam sand, the internal pressure of the cavity increases due to evaporation of moisture and thermal expansion of bubbles during the heating and curing (firing) process of the foam sand. In the product, a water-soluble binder and aggregate are accumulated on the surface layer portion to form a dense hardened layer having high strength, while a brittle portion having a low density is formed inside. For this reason, the core made of foam sand is excellent in disintegration after casting and can be easily removed from the cast product while ensuring sufficient strength as a core during casting.
発泡砂は、金型内で加熱、硬化する際、水蒸気及びガスを発生するため、これらを金型のキャビティの外部に円滑に排出する必要がある。そこで、発泡砂の造型用の金型には、水蒸気及びガスを排出するためのスリット、あるいは、通路が設けられる。また、特許文献1には、発泡砂用のものではないが、金型にガス抜き孔を設けて、シェル砂を金型のキャビティ内で焼成する際、発生するガスを金型のキャビティから排出する点が記載されている。
Foamed sand generates water vapor and gas when heated and hardened in the mold, so it is necessary to discharge these to the outside of the mold cavity smoothly. Accordingly, a mold for foaming sand is provided with a slit or a passage for discharging water vapor and gas. Further, Patent Document 1 is not for foaming sand, but a gas vent hole is provided in the mold, and when the shell sand is fired in the mold cavity, the generated gas is discharged from the mold cavity. The point to do is described.
発泡砂を用いて砂型を造型する場合、次のような問題がある。
発泡砂の加熱、硬化時間(焼成時間)を短縮するためには、水蒸気をいかに早く金型のキャビティから排出するかが重要である。しかし、発泡砂が加熱、硬化する過程で、水蒸気及びガスと共に水溶性のバインダーがガス抜き用のスリット、通路から流出するため、造型の繰返しにより、ガス抜き用のスリット、通路に固化したバインダーが堆積して、水蒸気及びガスの排出が妨げられることがある。水蒸気及びガスの円滑な排出が妨げられると、発泡砂の焼成に時間がかかり、問題となる。 When forming a sand mold using foam sand, there are the following problems.
In order to shorten the heating and curing time (baking time) of the foam sand, it is important how quickly water vapor is discharged from the mold cavity. However, in the process of foaming sand heating and hardening, water-soluble binder flows out from the slits and passages along with water vapor and gas. It can build up and prevent the discharge of water vapor and gases. If smooth discharge of water vapor and gas is hindered, it takes time to fire the foamed sand, which is a problem.
発泡砂の加熱、硬化時間(焼成時間)を短縮するためには、水蒸気をいかに早く金型のキャビティから排出するかが重要である。しかし、発泡砂が加熱、硬化する過程で、水蒸気及びガスと共に水溶性のバインダーがガス抜き用のスリット、通路から流出するため、造型の繰返しにより、ガス抜き用のスリット、通路に固化したバインダーが堆積して、水蒸気及びガスの排出が妨げられることがある。水蒸気及びガスの円滑な排出が妨げられると、発泡砂の焼成に時間がかかり、問題となる。 When forming a sand mold using foam sand, there are the following problems.
In order to shorten the heating and curing time (baking time) of the foam sand, it is important how quickly water vapor is discharged from the mold cavity. However, in the process of foaming sand heating and hardening, water-soluble binder flows out from the slits and passages along with water vapor and gas. It can build up and prevent the discharge of water vapor and gases. If smooth discharge of water vapor and gas is hindered, it takes time to fire the foamed sand, which is a problem.
本発明は、上記の点に鑑みて成されたものであり、発泡砂を金型のキャビティ内で加熱、硬化する際、キャビティ内から水蒸気及びガスを円滑に排出して硬化時間を短縮することを目的とする。
The present invention has been made in view of the above points, and when heating and curing foam sand in a mold cavity, water vapor and gas are smoothly discharged from the cavity to shorten the curing time. With the goal.
上記の課題を解決するために、本発明は、バインダーを骨材と共に撹拌して発泡させた発泡砂を金型のキャビティに充填し、加熱、固化して造型品を得る砂型造型方法及び砂型造型装置において、
前記金型を型締めして前記キャビティを形成し、該キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を設けることを特徴とする。 In order to solve the above problems, the present invention provides a sand mold molding method and a sand mold molding method in which a foamed sand obtained by stirring a binder together with an aggregate and foaming is filled in a cavity of a mold and heated and solidified to obtain a molded product. In the device
The mold is clamped to form the cavity, and the cavity is filled with foamed sand, and then the mold is slightly opened to provide a gap between the molds while maintaining the cavity. And
前記金型を型締めして前記キャビティを形成し、該キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を設けることを特徴とする。 In order to solve the above problems, the present invention provides a sand mold molding method and a sand mold molding method in which a foamed sand obtained by stirring a binder together with an aggregate and foaming is filled in a cavity of a mold and heated and solidified to obtain a molded product. In the device
The mold is clamped to form the cavity, and the cavity is filled with foamed sand, and then the mold is slightly opened to provide a gap between the molds while maintaining the cavity. And
(発明の態様)
以下に、本発明において特許請求が可能と認識される発明(以下、「請求可能発明」という場合がある。)の態様をいくつか例示し、それらについて説明する。各態様は請求項と同様に、項に区分し、各項に番号を付し、必要に応じて他の項の番号を引用する形式で記載する。これは、あくまでも請求可能発明の理解を容易にするためであり、請求可能発明を構成する構成要素の組み合わせを、以下の各項に記載されたものに限定する趣旨ではない。つまり、請求可能発明は、各項に付随する記載,実施例の記載等を参酌して解釈されるべきであり、その解釈に従う限りにおいて、各項の態様にさらに他の構成要素を付加した態様も、また、各項の態様から構成要素を削除した態様も、請求可能発明の一態様となり得るのである。なお、以下の(1)乃至(6)の内容が請求項1乃至6にそれぞれ対応する。 (Aspect of the Invention)
In the following, some aspects of the invention that can be claimed in the present invention (hereinafter sometimes referred to as “claimable invention”) will be exemplified and described. As with the claims, each aspect is divided into sections, each section is numbered, and is described in a form that cites the numbers of other sections as necessary. This is for the purpose of facilitating the understanding of the claimable invention, and is not intended to limit the combinations of the constituent elements constituting the claimable invention to those described in the following sections. In other words, the claimable invention should be construed in consideration of the description accompanying each section, the description of the embodiments, etc., and as long as the interpretation is followed, another aspect is added to the form of each section. In addition, an aspect in which constituent elements are deleted from the aspect of each item can be an aspect of the claimable invention. The following contents (1) to (6) correspond toclaims 1 to 6, respectively.
以下に、本発明において特許請求が可能と認識される発明(以下、「請求可能発明」という場合がある。)の態様をいくつか例示し、それらについて説明する。各態様は請求項と同様に、項に区分し、各項に番号を付し、必要に応じて他の項の番号を引用する形式で記載する。これは、あくまでも請求可能発明の理解を容易にするためであり、請求可能発明を構成する構成要素の組み合わせを、以下の各項に記載されたものに限定する趣旨ではない。つまり、請求可能発明は、各項に付随する記載,実施例の記載等を参酌して解釈されるべきであり、その解釈に従う限りにおいて、各項の態様にさらに他の構成要素を付加した態様も、また、各項の態様から構成要素を削除した態様も、請求可能発明の一態様となり得るのである。なお、以下の(1)乃至(6)の内容が請求項1乃至6にそれぞれ対応する。 (Aspect of the Invention)
In the following, some aspects of the invention that can be claimed in the present invention (hereinafter sometimes referred to as “claimable invention”) will be exemplified and described. As with the claims, each aspect is divided into sections, each section is numbered, and is described in a form that cites the numbers of other sections as necessary. This is for the purpose of facilitating the understanding of the claimable invention, and is not intended to limit the combinations of the constituent elements constituting the claimable invention to those described in the following sections. In other words, the claimable invention should be construed in consideration of the description accompanying each section, the description of the embodiments, etc., and as long as the interpretation is followed, another aspect is added to the form of each section. In addition, an aspect in which constituent elements are deleted from the aspect of each item can be an aspect of the claimable invention. The following contents (1) to (6) correspond to
(1)バインダーを骨材と共に撹拌して発泡させた発泡砂を金型のキャビティに充填し、加熱、固化して造型品を得る砂型造型方法において、
前記金型を型締めして前記キャビティを形成し、該キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を設けることを特徴とする砂型造型方法。
(2)(1)において、前記金型の型締め力を低下させて、前記金型からの反力により前記金型間に隙間を設けることを特徴とする砂型造型方法。
(3)(1)又は(2)において、前記金型間の隙間は、0.22mm~0.36mmであることを特徴とする請求項1又は2に記載の砂型造型方法。
(4)型締めによりキャビティを形成する金型と、前記金型を開閉する型締め装置と、バインダーを骨材と共に撹拌して発泡させた発泡砂を前記キャビティに充填する充填装置と、前記キャビティ内の発泡砂を加熱する加熱装置と、を備え、
前記型締め装置は、前記キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を形成することを特徴とする砂型造型装置
(5)(4)において、前記型締め装置は、型締め力を低下させて、前記金型からの反力により前記金型間に隙間を形成することを特徴とする砂型造型装置。
(6)(4)又は(5)において、前記金型間の隙間は、0.22mm~0.36mmであることを特徴とする砂型造型装置。
(1)及び(4)の砂型造型方法及び装置によれば、金型のキャビティ内で発泡砂を加熱、硬化する際、金型間に微小な隙間を設けることにより、水蒸気及びガスが金型間の隙間から円滑に外部に排出されるので、硬化時間を短縮することができる。
金型のキャビティから水蒸気及びガスを排出する通路に固化したバインダーが堆積した場合でも、金型間の隙間により、水蒸気及びガスをキャビティから外部に確実に排出することができる。
このとき、金型間の隙間が充分小さく、キャビティの形状及び寸法が維持されるので、造型品の寸法精度に影響することがない。
(2)及び(5)の砂型造型方法及び装置によれば、金型からの反力に応じて金型間の隙間を調整することができる。
(3)及び(6)の砂型造型方法及び装置によれば、隙間を最適化して望ましい造型を行うことができる。
(7)(5)又は(6)において、前記型締め装置は、エアシリンダによって前記金型の型締めを行い、前記エアシリンダに供給する圧縮エアの圧力を低下させて型締め力を低下させることを特徴とする砂型造型装置。 (1) In a sand molding method of filling a mold cavity with foamed sand that is stirred and foamed with an aggregate, heated and solidified to obtain a molded product,
The mold is clamped to form the cavity, and the cavity is filled with foamed sand, and then the mold is slightly opened to provide a gap between the molds while maintaining the cavity. Sand mold making method.
(2) In the method of (1), the mold clamping force of the mold is reduced, and a gap is provided between the molds by a reaction force from the mold.
(3) In the method of (1) or (2), the gap between the molds is 0.22 mm to 0.36 mm.
(4) A mold that forms a cavity by mold clamping, a mold clamping apparatus that opens and closes the mold, a filling apparatus that fills the cavity with foamed sand that is stirred and foamed with an aggregate, and the cavity A heating device for heating the foamed sand inside,
The mold clamping device is characterized in that, after filling the cavity with foamed sand, the mold is slightly opened to form a gap between the molds while maintaining the cavity. ) In (4), the mold clamping device reduces a mold clamping force and forms a gap between the molds by a reaction force from the molds.
(6) The sand mold making apparatus according to (4) or (5), wherein a gap between the molds is 0.22 mm to 0.36 mm.
According to the sand mold making method and apparatus of (1) and (4), when heating and curing the foamed sand in the cavity of the mold, a minute gap is provided between the molds so that water vapor and gas are transferred to the mold. Since it is smoothly discharged to the outside through the gaps between them, the curing time can be shortened.
Even when the solidified binder accumulates in the passage for discharging water vapor and gas from the mold cavity, the water vapor and gas can be reliably discharged from the cavity to the outside by the gap between the molds.
At this time, since the gap between the molds is sufficiently small and the shape and dimensions of the cavity are maintained, the dimensional accuracy of the molded product is not affected.
According to the sand mold making method and apparatus of (2) and (5), the gap between the molds can be adjusted according to the reaction force from the mold.
According to the sand mold making method and apparatus of (3) and (6), it is possible to perform a desired mold by optimizing the gap.
(7) In (5) or (6), the mold clamping device performs mold clamping of the mold by an air cylinder, and reduces the pressure of compressed air supplied to the air cylinder to reduce the clamping force. A sand mold making device.
前記金型を型締めして前記キャビティを形成し、該キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を設けることを特徴とする砂型造型方法。
(2)(1)において、前記金型の型締め力を低下させて、前記金型からの反力により前記金型間に隙間を設けることを特徴とする砂型造型方法。
(3)(1)又は(2)において、前記金型間の隙間は、0.22mm~0.36mmであることを特徴とする請求項1又は2に記載の砂型造型方法。
(4)型締めによりキャビティを形成する金型と、前記金型を開閉する型締め装置と、バインダーを骨材と共に撹拌して発泡させた発泡砂を前記キャビティに充填する充填装置と、前記キャビティ内の発泡砂を加熱する加熱装置と、を備え、
前記型締め装置は、前記キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を形成することを特徴とする砂型造型装置
(5)(4)において、前記型締め装置は、型締め力を低下させて、前記金型からの反力により前記金型間に隙間を形成することを特徴とする砂型造型装置。
(6)(4)又は(5)において、前記金型間の隙間は、0.22mm~0.36mmであることを特徴とする砂型造型装置。
(1)及び(4)の砂型造型方法及び装置によれば、金型のキャビティ内で発泡砂を加熱、硬化する際、金型間に微小な隙間を設けることにより、水蒸気及びガスが金型間の隙間から円滑に外部に排出されるので、硬化時間を短縮することができる。
金型のキャビティから水蒸気及びガスを排出する通路に固化したバインダーが堆積した場合でも、金型間の隙間により、水蒸気及びガスをキャビティから外部に確実に排出することができる。
このとき、金型間の隙間が充分小さく、キャビティの形状及び寸法が維持されるので、造型品の寸法精度に影響することがない。
(2)及び(5)の砂型造型方法及び装置によれば、金型からの反力に応じて金型間の隙間を調整することができる。
(3)及び(6)の砂型造型方法及び装置によれば、隙間を最適化して望ましい造型を行うことができる。
(7)(5)又は(6)において、前記型締め装置は、エアシリンダによって前記金型の型締めを行い、前記エアシリンダに供給する圧縮エアの圧力を低下させて型締め力を低下させることを特徴とする砂型造型装置。 (1) In a sand molding method of filling a mold cavity with foamed sand that is stirred and foamed with an aggregate, heated and solidified to obtain a molded product,
The mold is clamped to form the cavity, and the cavity is filled with foamed sand, and then the mold is slightly opened to provide a gap between the molds while maintaining the cavity. Sand mold making method.
(2) In the method of (1), the mold clamping force of the mold is reduced, and a gap is provided between the molds by a reaction force from the mold.
(3) In the method of (1) or (2), the gap between the molds is 0.22 mm to 0.36 mm.
(4) A mold that forms a cavity by mold clamping, a mold clamping apparatus that opens and closes the mold, a filling apparatus that fills the cavity with foamed sand that is stirred and foamed with an aggregate, and the cavity A heating device for heating the foamed sand inside,
The mold clamping device is characterized in that, after filling the cavity with foamed sand, the mold is slightly opened to form a gap between the molds while maintaining the cavity. ) In (4), the mold clamping device reduces a mold clamping force and forms a gap between the molds by a reaction force from the molds.
(6) The sand mold making apparatus according to (4) or (5), wherein a gap between the molds is 0.22 mm to 0.36 mm.
According to the sand mold making method and apparatus of (1) and (4), when heating and curing the foamed sand in the cavity of the mold, a minute gap is provided between the molds so that water vapor and gas are transferred to the mold. Since it is smoothly discharged to the outside through the gaps between them, the curing time can be shortened.
Even when the solidified binder accumulates in the passage for discharging water vapor and gas from the mold cavity, the water vapor and gas can be reliably discharged from the cavity to the outside by the gap between the molds.
At this time, since the gap between the molds is sufficiently small and the shape and dimensions of the cavity are maintained, the dimensional accuracy of the molded product is not affected.
According to the sand mold making method and apparatus of (2) and (5), the gap between the molds can be adjusted according to the reaction force from the mold.
According to the sand mold making method and apparatus of (3) and (6), it is possible to perform a desired mold by optimizing the gap.
(7) In (5) or (6), the mold clamping device performs mold clamping of the mold by an air cylinder, and reduces the pressure of compressed air supplied to the air cylinder to reduce the clamping force. A sand mold making device.
本発明によれば、発泡砂を金型のキャビティ内で加熱、硬化する際、金型間の隙間を通してキャビティ内から水蒸気及びガスを円滑に排出することができ、硬化時間を短縮することができる。
According to the present invention, when foaming sand is heated and cured in the mold cavity, water vapor and gas can be smoothly discharged from the cavity through the gap between the molds, and the curing time can be shortened. .
以下、本発明の一実施形態を図面に基づいて詳細に説明する。
図1に示すように、本実施形態に係る砂型造型装置1は、発泡砂を固めて砂中子(砂型)を造型するものであって、キャビティCを形成する金型2と、金型2のキャビティCに発泡砂Sを充填するための充填装置3と、金型2の開閉を行う型締め装置4とを備えている。 Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
As shown in FIG. 1, a sandmold making apparatus 1 according to the present embodiment forms a sand core (sand mold) by solidifying foam sand, and includes a mold 2 that forms a cavity C, and a mold 2. A filling device 3 for filling the cavity C with foam sand S and a mold clamping device 4 for opening and closing the mold 2.
図1に示すように、本実施形態に係る砂型造型装置1は、発泡砂を固めて砂中子(砂型)を造型するものであって、キャビティCを形成する金型2と、金型2のキャビティCに発泡砂Sを充填するための充填装置3と、金型2の開閉を行う型締め装置4とを備えている。 Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
As shown in FIG. 1, a sand
本実施形態において使用する発泡砂Sは、骨材である砂と、水ガラス(ケイ酸ナトリウム)、水及び界面活性剤を含む水溶性無機バインダーとを混合し、混練して発泡状態としたものである。発泡砂Sを構成する粒子の状態のイメージを図6に示す。図6(A)は、砂の粒子7の表面に泡8が吸着した状態を示し、図6(B)は、泡8の一部を拡大して示している。図6(B)に示すように、発泡砂Sは、水ガラス水溶液(水を符号10、水ガラスを符号11で示す)の表面を界面活性剤9で覆って泡8を形成し、この泡8が界面活性剤9を介して砂の粒子7の表面に吸着して発泡状態となっており、適度な粘性を有している。ここで、砂に対して、水ガラスのモル比1.0~3.0、重量比0.4~3.0%、水の重量比1.5~5.0%、界面活性剤の重量比0.003~2.0%程度とすることにより、適度な粘性を有する発泡砂Sを得ることができる。
The foamed sand S used in the present embodiment is a mixture of sand as an aggregate and water glass (sodium silicate), water-soluble inorganic binder containing water and a surfactant, and kneaded into a foamed state. It is. An image of the state of the particles constituting the foamed sand S is shown in FIG. 6A shows a state in which the bubbles 8 are adsorbed on the surface of the sand particles 7, and FIG. 6B shows a part of the bubbles 8 in an enlarged manner. As shown in FIG. 6 (B), the foam sand S forms a foam 8 by covering the surface of a water glass aqueous solution (water is indicated by reference numeral 10 and water glass is indicated by reference numeral 11) with a surfactant 9. 8 is adsorbed on the surface of the sand particles 7 through the surfactant 9 to be in a foamed state, and has an appropriate viscosity. Here, the molar ratio of water glass to sand is 1.0 to 3.0, the weight ratio is 0.4 to 3.0%, the weight ratio of water is 1.5 to 5.0%, the weight of the surfactant. By setting the ratio to about 0.003 to 2.0%, foam sand S having an appropriate viscosity can be obtained.
図1を参照して、金型2は、パーティングラインPによって分割された固定型12と可動型13とを備え、固定型12と可動型13とを型締めしてキャビティCを形成する。固定型12は、固定ベース14に固定されている。可動型13は、移動可能な可動ベース15に固定され、可動ベース15と共に移動して金型2の開閉を行う。固定型12及び可動型13は、ヒータ等の加熱装置Hによって150℃~300℃程度に加熱され、キャビティCに充填された発泡砂Sの水分を蒸発させて発泡砂Sを固化させる。金型2には、キャビティC内において、発泡砂Sが加熱、硬化する際にガス及び水蒸気を外部に排出するためのスリット16等の排出通路を設けてもよい。
Referring to FIG. 1, the mold 2 includes a fixed mold 12 and a movable mold 13 divided by a parting line P, and the fixed mold 12 and the movable mold 13 are clamped to form a cavity C. The fixed mold 12 is fixed to the fixed base 14. The movable mold 13 is fixed to a movable movable base 15 and moves together with the movable base 15 to open and close the mold 2. The fixed mold 12 and the movable mold 13 are heated to about 150 ° C. to 300 ° C. by a heating device H such as a heater, and the foam sand S filled in the cavity C is evaporated to solidify the foam sand S. The mold 2 may be provided with a discharge passage such as a slit 16 for discharging gas and water vapor to the outside when the foamed sand S is heated and hardened in the cavity C.
金型2の固定型12及び可動型13には、それぞれ離型装置17が設けられている。離型装置17は、キャビティC内に向って進退動可能に設けられた複数の押出ピン18と、複数の押出ピン18の基部に連結された押出板19と、固定ベース14及び可動ベース15と押出板19との間に設けられた押出バネ20とを備えている。そして、押出バネ20のバネ力により、押出板19を介して複数の押出ピン18を押圧して、押出ピン18の先端部をキャビティC内に突出させるようになっている。両側の押出板19には、それぞれ先端部が互いに対向する後退ピン21が取付けられている。そして、固定型12と可動型13とを閉じたとき、これらの後退ピン21の先端部が互いに当接して、押出板19を押出バネ20のバネ力に抗して移動させることにより、押出ピン18をキャビティCから後退させるようになっている。これにより、押出ピン18は、金型2の開閉に連動し、金型2を閉じたとき、キャビティC内から後退し、金型2を開いたとき、キャビティC内に突出して造型した中子を離型する。
A mold release device 17 is provided for each of the fixed mold 12 and the movable mold 13 of the mold 2. The mold release device 17 includes a plurality of extrusion pins 18 provided so as to be movable back and forth in the cavity C, an extrusion plate 19 connected to the bases of the plurality of extrusion pins 18, a fixed base 14 and a movable base 15. An extrusion spring 20 provided between the extrusion plate 19 and the extrusion plate 19 is provided. Then, the plurality of push pins 18 are pressed through the push plate 19 by the spring force of the push springs 20 so that the tips of the push pins 18 protrude into the cavity C. Retraction pins 21 whose front ends are opposed to each other are attached to the extrusion plates 19 on both sides. When the fixed mold 12 and the movable mold 13 are closed, the tip portions of the retreat pins 21 come into contact with each other, and the push plate 19 is moved against the spring force of the push spring 20 to thereby push the push pin. 18 is retracted from the cavity C. Thus, the extrusion pin 18 is interlocked with the opening and closing of the mold 2, retracted from the cavity C when the mold 2 is closed, and the core formed by projecting into the cavity C when the mold 2 is opened. Release the mold.
充填装置3は、発泡砂Sを混練し、貯留する砂槽22と、砂槽22内の発泡砂Sを加圧する加圧機構23と、砂槽22を金型2のキャビティCに接続する充填口24とを備えている。そして、固定型12と可動型13とを閉じて型締めした金型2上に砂槽22をセットし、加圧機構23によって砂槽22内の発泡砂Sを加圧することにより、充填口24を介して金型2のキャビティC内に発泡砂Sを充填する。
The filling device 3 kneads and stores foam sand S, a pressurizing mechanism 23 that pressurizes foam sand S in the sand tank 22, and filling that connects the sand tank 22 to the cavity C of the mold 2. And a mouth 24. Then, the sand tank 22 is set on the mold 2 which is closed and clamped by closing the fixed mold 12 and the movable mold 13, and the foaming sand S in the sand tank 22 is pressurized by the pressurizing mechanism 23, thereby filling the filling port 24. The foamed sand S is filled into the cavity C of the mold 2 via.
型締め装置4は、可動ベース15を駆動する複動式のエアシリンダ26と、エアシリンダ26に圧縮エアを供給するエア源27と、エア源27からエアシリンダ26への圧縮エアの供給を切換えて、可動ベース15を前進及び後退させる切換弁28と、エアシリンダに供給する圧縮エアの圧力を調整する圧力調整弁29と、エアシリンダ26に供給された圧縮エアの圧力を検出する圧力計30と、切換弁28及び圧力調整弁29の作動を制御する制御装置31とを備えている。
The mold clamping device 4 switches the double-acting air cylinder 26 that drives the movable base 15, the air source 27 that supplies compressed air to the air cylinder 26, and the supply of compressed air from the air source 27 to the air cylinder 26. The switching valve 28 for moving the movable base 15 forward and backward, the pressure adjusting valve 29 for adjusting the pressure of the compressed air supplied to the air cylinder, and the pressure gauge 30 for detecting the pressure of the compressed air supplied to the air cylinder 26 And a control device 31 that controls the operation of the switching valve 28 and the pressure regulating valve 29.
制御装置31は、切換弁28を制御し、圧縮エアの供給を切換えて複動式のエアシリンダ26の作動ロッド26Aを伸縮させることにより、可動ベース15と共に可動型13を進退動させて金型2の開閉を行う。また、型締め時に圧力計30の検出圧力に基づいて圧力調整弁29を作動させ、エアシリンダ26に供給する圧縮エアの圧力を調整することにより、型締め力を調整する。これにより、金型2のキャビティC内で発泡砂Sが加熱、硬化する際、エアシリンダ26による型締め力を低下させると、キャビティC内の圧力、離型装置17の押出バネ20のバネ力、及び、金型2の反りによる反力により、可動型13が僅かに後退して、固定型12と可動型13とのパーティングラインPに微小な隙間L(図2(C)参照)が形成され、この隙間Lを調整することができる。
The control device 31 controls the switching valve 28, switches the supply of compressed air, and expands / contracts the actuating rod 26A of the double-acting air cylinder 26, thereby moving the movable mold 13 together with the movable base 15 to move the mold. 2 is opened and closed. Further, the mold clamping force is adjusted by operating the pressure adjustment valve 29 based on the pressure detected by the pressure gauge 30 during mold clamping and adjusting the pressure of the compressed air supplied to the air cylinder 26. Thereby, when foaming sand S is heated and hardened in the cavity C of the mold 2, if the clamping force by the air cylinder 26 is reduced, the pressure in the cavity C and the spring force of the extrusion spring 20 of the mold release device 17 are reduced. Due to the reaction force caused by the warp of the mold 2, the movable mold 13 is slightly retracted, and a minute gap L (see FIG. 2C) is formed in the parting line P between the fixed mold 12 and the movable mold 13. It is formed and this gap L can be adjusted.
次に、砂型造型装置1により、砂中子を造型する工程について説明する。
図2(A)に示すように、型締め装置4により可動型13を駆動して金型2を閉じ、型締めしてキャビティCを形成し、金型2に充填装置3をセットする。このとき、離型装置17の押出ピン18は、上述のように型締めに連動してキャビティCから後退する。金型2を加熱装置Hによって予め加熱した状態で、充填装置3の加圧機構23を作動させて、砂槽22内の発泡砂Sを充填口24を通して加熱された金型2のキャビティCに充填する。発泡砂SのキャビティCへの充填が完了した状態を図2(B)に示す。金型2のキャビティC内に充填された発泡砂Sは、加熱により水分が蒸発して硬化する。 Next, a process for forming a sand core by the sandmold making apparatus 1 will be described.
As shown in FIG. 2A, themovable mold 13 is driven by the mold clamping device 4 to close the mold 2, the mold is clamped to form a cavity C, and the filling device 3 is set in the mold 2. At this time, the extrusion pin 18 of the mold release device 17 moves backward from the cavity C in conjunction with the mold clamping as described above. In a state where the mold 2 is preheated by the heating device H, the pressurizing mechanism 23 of the filling device 3 is operated, and the foamed sand S in the sand tank 22 enters the cavity C of the mold 2 heated through the filling port 24. Fill. FIG. 2B shows a state where the filling of the foam sand S into the cavity C is completed. The foamed sand S filled in the cavity C of the mold 2 evaporates and hardens when heated.
図2(A)に示すように、型締め装置4により可動型13を駆動して金型2を閉じ、型締めしてキャビティCを形成し、金型2に充填装置3をセットする。このとき、離型装置17の押出ピン18は、上述のように型締めに連動してキャビティCから後退する。金型2を加熱装置Hによって予め加熱した状態で、充填装置3の加圧機構23を作動させて、砂槽22内の発泡砂Sを充填口24を通して加熱された金型2のキャビティCに充填する。発泡砂SのキャビティCへの充填が完了した状態を図2(B)に示す。金型2のキャビティC内に充填された発泡砂Sは、加熱により水分が蒸発して硬化する。 Next, a process for forming a sand core by the sand
As shown in FIG. 2A, the
ここで、キャビティC内に充填された発泡砂Cが加熱、硬化する過程について図7を参照して説明する。図7(A)に示すように、金型2のキャビティC内では、加熱により、発泡砂Sの気泡8が膨張してキャビティCの内圧が上昇する。そして、図7(B)に示すように、気泡8が金型2のキャビティCの内壁に沿って移動してパーティングラインPに設けられたスリット16等によって形成された通路を通って外部へ排出される。このとき、発泡砂Sを組成する水ガラス(バインダー)及び骨材がキャビティCの内壁側に押しやられて、キャビティCの内壁付近の水ガラス及び骨材の密度が高まる。その結果、キャビティC内で固化した砂中子Wは、キャビティCの内壁に接した表層部に水ガラス及び骨材の密度が高く緻密な硬化層33が形成され、内部の密度が低下し、中心部には、崩壊し易い脆弱部34が形成される。
Here, the process of heating and hardening the foamed sand C filled in the cavity C will be described with reference to FIG. As shown in FIG. 7A, in the cavity C of the mold 2, the bubbles 8 of the foamed sand S expand due to heating, and the internal pressure of the cavity C rises. Then, as shown in FIG. 7B, the bubbles 8 move along the inner wall of the cavity C of the mold 2 to the outside through a passage formed by the slit 16 or the like provided in the parting line P. Discharged. At this time, the water glass (binder) and the aggregate composing the foam sand S are pushed toward the inner wall side of the cavity C, and the density of the water glass and the aggregate near the inner wall of the cavity C is increased. As a result, the sand core W solidified in the cavity C is formed with a dense hardened layer 33 having a high density of water glass and aggregate on the surface layer portion in contact with the inner wall of the cavity C, and the internal density decreases. A fragile portion 34 that easily collapses is formed at the center.
また、キャビティCの内壁側に押しやられた水ガラス(バインダー)は、水蒸気及びガスと共にスリット16等からなる通路に侵入して外部に放出される。この通路に侵入したバインダーは、硬化して通路に固着する。このようにして通路に固着したバインダーが堆積して通路が塞がれると、水蒸気及びガスの円滑な排出が阻害され、焼成時間が長くなり、造型不良の原因となる。
Further, the water glass (binder) pushed to the inner wall side of the cavity C enters the passage made of the slit 16 and the like together with water vapor and gas and is discharged to the outside. The binder that has entered the passage is cured and fixed to the passage. When the binder fixed in the passage is deposited in this way and the passage is blocked, smooth discharge of water vapor and gas is hindered, and the firing time becomes longer, resulting in molding failure.
本実施形態では、金型2のキャビティCへの発泡砂Sの充填完了後、型締め装置4の制御装置31により、圧力計30の検出圧力に基づき、圧力調整弁29を作動させてエアシリンダ26への圧縮エアの供給圧力を所定圧力だけ減圧し、型締め力を低下させる。これにより、図2(C)に示すように、発泡砂Sの加熱、硬化により上昇したキャビティC内の圧力、離型装置17の押出バネ20のバネ力、及び、金型2の反りによる反力により、可動型13が僅かに後退して、固定型12と可動型13とのパーティングラインPに微小な隙間Lが形成される。そして、金型2のキャビティC内で発泡砂Sの加熱、硬化時に生じるガス及び水蒸気がこの微小な隙間Lを通して外部に円滑に排出される。その結果、発泡砂Sの固化を促進することができ、焼成時間を短縮することができる。
In the present embodiment, after the filling of the foam sand S into the cavity C of the mold 2 is completed, the control device 31 of the mold clamping device 4 operates the pressure adjustment valve 29 based on the detected pressure of the pressure gauge 30, so that the air cylinder The supply pressure of compressed air to 26 is reduced by a predetermined pressure, and the clamping force is reduced. As a result, as shown in FIG. 2C, the pressure in the cavity C increased by heating and hardening of the foamed sand S, the spring force of the extrusion spring 20 of the mold release device 17, and the warpage due to the warp of the mold 2. Due to the force, the movable mold 13 is slightly retracted, and a minute gap L is formed in the parting line P between the fixed mold 12 and the movable mold 13. The gas and water vapor generated during heating and hardening of the foamed sand S in the cavity C of the mold 2 are smoothly discharged to the outside through the minute gap L. As a result, solidification of the foamed sand S can be promoted, and the firing time can be shortened.
このとき、微小な隙間Lは、ガス及び水蒸気を円滑に排出できる程度の僅かな隙間であり、可動型13の移動量も僅かであるから、キャビティCの形状及び寸法が維持されるので、造型する中子の形状及び寸法精度に影響しない。また、キャビティC内の圧力、離型装置17の押出バネ20のバネ力、及び、金型2の反りの反力により、可動型13が僅かに移動して固定型12との間に微小な隙間Lを形成するので、金型2間のパーティングラインP、スリット16へのバインダーの堆積量にかかわらず、一定の微小な隙間Lを確保することができる。その結果、発泡砂Sの加熱、硬化時に生じるガス及び水蒸気を確実に外部に排出することができ、焼成時間を短縮して良好な造型品を得ることができる。
At this time, the minute gap L is a slight gap that allows gas and water vapor to be smoothly discharged, and the amount of movement of the movable mold 13 is also small, so that the shape and dimensions of the cavity C are maintained. Does not affect the core shape and dimensional accuracy. Further, the movable mold 13 is slightly moved by the pressure in the cavity C, the spring force of the extrusion spring 20 of the mold release device 17, and the warping reaction force of the mold 2, so that the movable mold 13 is slightly moved from the fixed mold 12. Since the gap L is formed, a constant minute gap L can be secured regardless of the amount of binder deposited on the parting line P and the slit 16 between the molds 2. As a result, the gas and water vapor generated during the heating and curing of the foamed sand S can be reliably discharged to the outside, and a good molded product can be obtained by shortening the firing time.
金型2のキャビティC内の発泡砂Sが固化した後、制御装置31により切換弁28を作動させ、複動式のエアシリンダ26への圧縮エアの供給を切換えて、可動ベース15と共に可動型13を後退させて金型2を開き、造型された砂中子を取出す。このとき、型開きに連動して離型装置17の後退ピン21の先端部が離間し、押出バネ20のバネ力により押出板19が移動し、押出ピン18がキャビティC内に突出して造型した砂中子を離型する。
After the foamed sand S in the cavity C of the mold 2 is solidified, the control valve 31 is operated by the control device 31 to switch the supply of compressed air to the double-acting air cylinder 26, and the movable base 15 is moved together with the movable base 15. 13 is retracted, the mold 2 is opened, and the molded sand core is taken out. At this time, the tip of the retreat pin 21 of the mold release device 17 is separated in conjunction with the mold opening, the push plate 19 is moved by the spring force of the push spring 20, and the push pin 18 protrudes into the cavity C to make a mold. Release the sand core.
次に、上述の工程において、金型2間のパーティングラインPに隙間Lを形成する際(図2(C)参照)のエアシリンダ26に供給する圧縮エアの圧力と、隙間Lの大きさ、及び、造型された砂中子の良否との関係について図3乃至図5を参照して説明する。
Next, in the above-described steps, the pressure of the compressed air supplied to the air cylinder 26 and the size of the gap L when the gap L is formed in the parting line P between the molds 2 (see FIG. 2C). The relationship between the quality of the molded sand core and quality will be described with reference to FIGS.
図3及び図4に示すように、型締め時のエアシリンダ26への圧縮エアの供給圧力0.35MPaに対して、供給圧力を低下させて、0.15MPa、0.10MPa及び0.05MPaとすることにより、隙間Lは、それぞれ、平均で0.22mm、0.25mm及び0.36mmとなった。これにより、図5に示すように、供給圧力を型締め時のまま0.35MPaとして、隙間Lを設けない場合には、造型品は、良品60%、不良品40%であるのに対して、供給圧力を0.10MPaに低下させて隙間Lを設けた場合、良品80%、不良品20%となり、さらに供給圧力を0.05MPaに低下させて隙間Lを増大した場合、100%の良品を得ることができた。
As shown in FIGS. 3 and 4, the supply pressure is reduced to 0.15 MPa, 0.10 MPa, and 0.05 MPa against the supply pressure of 0.35 MPa of compressed air to the air cylinder 26 during mold clamping. As a result, the gaps L were 0.22 mm, 0.25 mm, and 0.36 mm on average, respectively. Accordingly, as shown in FIG. 5, when the supply pressure is set to 0.35 MPa while the mold is clamped and the gap L is not provided, the molded product is 60% non-defective product and 40% defective product. When the supply pressure is reduced to 0.10 MPa and the gap L is provided, the non-defective product is 80% and the defective product is 20%. When the supply pressure is further reduced to 0.05 MPa and the gap L is increased, 100% good product is obtained. Could get.
なお、上記実施形態では、型締め装置4のエアシリンダ26への圧縮エアの供給圧力(型締め力)を低下させて、金型2間の反力により固定型12と可動型13との間に隙間Lを形成するようにしているが、可動型13の移動量を直接制御することにより、所定の隙間Lを形成するようにしてもよい。
In the above embodiment, the supply pressure (clamping force) of the compressed air to the air cylinder 26 of the mold clamping device 4 is reduced, and the reaction force between the molds 2 causes the space between the fixed mold 12 and the movable mold 13. However, the predetermined gap L may be formed by directly controlling the movement amount of the movable mold 13.
1…砂型造型装置、2…金型、C…キャビティ、H…加熱装置、L…隙間、S…発泡砂
DESCRIPTION OF SYMBOLS 1 ... Sand mold making apparatus, 2 ... Mold, C ... Cavity, H ... Heating apparatus, L ... Crevice, S ... Foam sand
Claims (6)
- バインダーを骨材と共に撹拌して発泡させた発泡砂を金型のキャビティに充填し、加熱、固化して造型品を得る砂型造型方法において、
前記金型を型締めして前記キャビティを形成し、該キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を設けることを特徴とする砂型造型方法。 In the sand mold making method, the foamed sand which is foamed by stirring the binder together with the aggregate is filled into the mold cavity, heated and solidified to obtain a molded product.
The mold is clamped to form the cavity, and the cavity is filled with foamed sand, and then the mold is slightly opened to provide a gap between the molds while maintaining the cavity. Sand mold making method. - 前記金型の型締め力を低下させて、前記金型からの反力により前記金型間に隙間を設けることを特徴とする請求項1に記載の砂型造型方法。 The sand mold making method according to claim 1, wherein a clamping force of the mold is reduced and a gap is provided between the molds by a reaction force from the mold.
- 前記金型間の隙間は、0.22mm~0.36mmであることを特徴とする請求項1又は2に記載の砂型造型方法。 3. The sand mold making method according to claim 1, wherein a gap between the molds is 0.22 mm to 0.36 mm.
- 型締めによりキャビティを形成する金型と、前記金型を開閉する型締め装置と、バインダーを骨材と共に撹拌して発泡させた発泡砂を前記キャビティに充填する充填装置と、前記キャビティ内の発泡砂を加熱する加熱装置と、を備え、
前記型締め装置は、前記キャビティ内に発泡砂を充填した後、前記金型を僅かに開いて前記キャビティを維持しつつ前記金型間に隙間を形成することを特徴とする砂型造型装置。 A mold for forming a cavity by mold clamping, a mold clamping apparatus for opening and closing the mold, a filling apparatus for filling the cavity with foamed sand obtained by stirring and foaming a binder together with an aggregate, and foaming in the cavity A heating device for heating the sand,
The mold clamping device is characterized in that after filling the cavity with foamed sand, the mold is slightly opened to form a gap between the molds while maintaining the cavity. - 前記型締め装置は、型締め力を低下させて、前記金型からの反力により前記金型間に隙間を形成することを特徴とする請求項4に記載の砂型造型装置。 The sand mold molding apparatus according to claim 4, wherein the mold clamping device reduces a mold clamping force and forms a gap between the molds by a reaction force from the mold.
- 前記金型間の隙間は、0.22mm~0.36mmであることを特徴とする請求項4又は5に記載の砂型造型装置。 The sand mold making apparatus according to claim 4 or 5, wherein a gap between the molds is 0.22 mm to 0.36 mm.
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CN201480003648.2A CN104884188A (en) | 2013-03-27 | 2014-01-22 | Sand-mold molding method and sand-mold molding apparatus |
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- 2014-01-22 WO PCT/JP2014/051273 patent/WO2014156246A1/en active Application Filing
- 2014-01-22 EP EP14776559.8A patent/EP2979776A4/en not_active Withdrawn
- 2014-01-22 US US14/780,116 patent/US20160045951A1/en not_active Abandoned
- 2014-02-13 TW TW103104720A patent/TW201440921A/en unknown
Patent Citations (3)
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JPH10263745A (en) * | 1997-03-18 | 1998-10-06 | Noritake Co Ltd | Precision casting method and flask |
JP2002192305A (en) | 2000-12-26 | 2002-07-10 | Aisin Takaoka Ltd | Method for manufacturing core for casting |
JP2007522947A (en) * | 2004-02-18 | 2007-08-16 | ホーメル フーズ,リミティド ライアビリティ カンパニー | Method of drying sand mold using vacuum |
Cited By (1)
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CN105014007A (en) * | 2015-08-21 | 2015-11-04 | 广东富华铸锻有限公司 | Application method of roughing sand calcination technology to casting and sand core |
Also Published As
Publication number | Publication date |
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CN104884188A (en) | 2015-09-02 |
TW201440921A (en) | 2014-11-01 |
JP2014188551A (en) | 2014-10-06 |
EP2979776A4 (en) | 2016-11-09 |
EP2979776A1 (en) | 2016-02-03 |
US20160045951A1 (en) | 2016-02-18 |
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