CN109128029B - Built-in functional tectorial membrane psammitolite casting mould of engine flywheel shell tide mould sand - Google Patents

Abstract

The invention discloses a die for casting a sand core with built-in functional precoated sand for a flywheel shell of an engine, which comprises an upper plate die, a lower plate die and a pouring system, wherein an upper die block corresponding to the upper plate die is arranged on the upper plate die, a lower die block corresponding to the lower plate die is arranged on the lower plate die, the upper plate die and the lower plate die are combined through green sand molding to form a die cavity, the pouring system is communicated with the die cavity, and a hot core box is arranged in the die cavity to form the sand core with the precoated sand core matched with the die cavity.

Description

Built-in functional tectorial membrane psammitolite casting mould of engine flywheel shell tide mould sand

Technical Field

The invention relates to a die, in particular to a die for casting a functional precoated sand core with built-in engine flywheel housing damp mould sand.

Background

The flywheel shell of the heavy truck engine is made of HT250 copper-chromium alloy castings, and a resin sand or damp mould sand casting process is generally selected; in the two processes of resin sand and damp mould sand, the resin sand is not the preferred process for mass production because of high manufacturing cost and slow loading speed; so the wet sand casting process is adopted by most casting enterprises;

at present, enterprises produce flywheel shells of China heavy-steam German Mannheim engines, and a tide sand molding process is also adopted, so that a 148-assembly line mass production mode is adopted; through practice, the inner cavity of the casting is self-cored by using the wet sand, and the high-temperature molten iron of the wet sand is filled and brushed for a long time, so that the ratio of sand hole defects is large, the surface quality of the casting is poor, and the quality requirement of a customer cannot be met; so we now choose the compound craft of the embedded core of sand precoated sand of damp mould; namely, precoated sand is arranged below the inner cavity of the casting to form a sand core so as to ensure the surface quality of the casting; three problems exist in the prior art, namely, the labor intensity of core making and molding procedures is high, and the labor cost is high; at present, each casting is internally provided with a precoated sand core with a single weight of 21 kg, and one person is difficult to finish in a high-temperature state when the precoated sand core is manufactured, so that two persons are configured to finish cooperatively; secondly, when the sand mould is molded, 21 kg of precoated sand mould is put into the cavity, one person cannot finish the operation, two persons are matched for core setting, and as the clearance between the inner cavity core and the sand form of the tide mould is only 5-6 mm and the matching is slightly not in place, sand is arranged, and a large-area sand hole is formed in the casting; thirdly, the precoated sand core accounts for higher total cost of the casting, and the measuring cost is 910.8 yuan/T (the cost of precoated sand materials and the core wages), so that the research and development of the casting mould for the inner precoated sand core of the wet mould sand of the flywheel shell of the automobile engine, which can overcome the defects, becomes a technical problem to be solved urgently by the person skilled in the art.

Disclosure of Invention

Aiming at the defects existing in the prior art, the invention provides the engine flywheel housing tidal mould sand built-in functional precoated sand core casting mould which is simple and compact in structure, convenient to use, capable of reducing labor intensity of workers, improving core manufacturing efficiency, reducing sand hole defects of castings, high in surface quality of cast components and greatly reducing casting cost.

The technical scheme for solving the technical problems is as follows:

the utility model provides an engine flywheel shell tide mould sand embeds functional tectorial membrane psammitolite casting mould, the mould includes last template mould, lower template mould and gating system, is equipped with the last type piece that corresponds with last template mould on the last template mould, is equipped with the lower type piece that corresponds with lower template mould on the lower template mould, goes up template mould and lower template mould and forms the die cavity through green sand molding involution, gating system and die cavity intercommunication are provided with hot core box made with die cavity assorted tectorial membrane psammitolite in the die cavity, wherein:

the hot core box comprises a hot core box fixed die and a hot core box movable die which are mutually involuted, and a cavity for forming a sand core with a built-in precoated sand for a flywheel shell damp mould of an automobile engine is formed between the hot core box fixed die and the hot core box movable die, wherein:

a group of movable mould supporting feet are arranged on the movable mould of the hot core box, two first positioning rod holes are symmetrically arranged on the surface of the movable mould of the hot core box, and four first reset rod holes are uniformly distributed on the surface of the movable mould of the hot core box;

four corners of the hot core box fixed die extend outwards to form positioning blocks, kidney-shaped positioning holes are formed in the positioning blocks, two second positioning rod holes matched with the first positioning rod holes are symmetrically formed in the surface of the hot core box fixed die, a plurality of core shooting holes are further formed in the surface of the hot core box fixed die, and four second reset rod holes matched with the first reset rod holes are uniformly distributed at corresponding positions of the surface of the hot core box fixed die;

the hot core box moving die is oppositely arranged on the hot core box fixed die, the hot core box moving die and the hot core box fixed die are assembled and positioned through a first positioning rod hole and a second positioning rod hole, and hot core box heating pipe holes for installing heating pipes are respectively formed in the side walls of the hot core box fixed die and the hot core box moving die.

The technical scheme of the invention is further defined as follows:

in the functional precoated sand core casting mold with the built-in engine flywheel shell damp mold sand, the upper template mold designs a concave-convex matched curve surface according to the external shape of the precoated sand core.

The invention has the technical effects that the removing part is replaced by the damp mould sand, the original process mould flat cover box is redesigned into the damp mould sand hanging sand, the upper template mould is used for replacing the non-functional precoated sand core outer template, the formed upper template mould is designed into a concave-convex matched curve surface according to the outer shape of the precoated sand core, the positioning and pressing of the built-in functional sand core are realized, so that the stability of the sand core in a cavity is ensured, the improved built-in precoated sand core not only has the functions of high temperature radiation resistance and scouring resistance of the original process precoated sand core, but also can not influence the positioning precision because of removing the non-functional parts of the sand core, and the dimensional precision grade of a casting is ensured.

In the engine flywheel housing wet-molding sand built-in functional precoated sand core casting mold, the core shooting holes are two groups, each group of core shooting holes is surrounded by 8 independent core shooting holes to form a circle, and the circle surrounded by the two groups of core shooting holes is concentric.

The invention has the technical effects that the jet port distribution design is determined according to the shape of the sand core, and the injected precoated sand is mainly ensured to jet the sand core into a solid state without dead angles.

In the engine flywheel shell wet-molding sand built-in functional precoated sand core casting mold, the hot core box is internally provided with reinforcing ribs.

In the engine flywheel housing wet-molding sand built-in functional precoated sand core casting mold, the thickness of the thinnest part of the wall thickness of the precoated sand core is 12mm.

In the engine flywheel housing wet-molding sand built-in functional precoated sand core casting mold, 6-8 reinforcing ribs are arranged in the precoated sand core, and the height of the reinforcing ribs is 10mm.

The beneficial effects of the invention are as follows:

firstly, analyzing the effect of a built-in precoated sand core used in an engine flywheel shell damp-mould sand casting process, wherein the casting defects such as sand holes, sand inclusion defects, flow marks and the like are easily formed mainly because the heat strength of a damp-mould inner cavity is insufficient during high-temperature molten iron heat radiation and scouring; mainly comprises a high temperature region in the casting process; the existing casting process adopts a bottom casting process of feeding molten iron into a small spigot of a flywheel housing, the high-temperature molten iron heat radiation area is shown in a figure (10), the upper surface of the inner cavity of the flywheel housing is shown in a shadow area part of a figure (11), the bottom lower wall of a cavity is gradually fully distributed by the molten iron feeding cavity due to the action of gravity, and heat radiation is generated on the bottom upper wall, namely a red area surface in the molten iron filling process, so that the surface strength of a red surface formed by damp sand is damaged, and the defects of sand holes, flow marks, sand filling sand inclusion and the like can be caused due to the fact that the intensity of the damp sand is insufficient; so the prior art design makes the inner cavity of the flywheel casing casting be formed by using a precoated sand core (12);

secondly, according to the multi-time tracking on-site process verification of the inventor, the action surface of the built-in precoated sand core to the high-temperature molten iron is truly the functional surface part of a built-in sand core diagram (11) of the precoated sand; according to the thought, a functional casting process of the embedded precoated sand core of the flywheel casing damp mold sand of the automobile engine is designed, the non-functional surface part of the embedded precoated sand is removed to the maximum extent, and in order to realize the functional sand core of the precoated sand, a set of precoated sand hot core box is redesigned; referring to fig. 5 and 6, a set of precoated sand hot core boxes redesigned by us are used for manufacturing a precoated sand functionalized precoated sand core; see fig. 8-9; the thickness of the thinnest part of the improved precoated sand core is designed to be 12mm; the height of the inner land root reinforcing rib is 10mm; see fig. 9; the removed part is replaced by damp mould sand; the original process mould flat cover box is redesigned into a wet mould sand hanging sand, and the figure 7 is used for replacing a non-functional precoated sand core external mould, and the hanging sand surface of a formed upper cavity of the wet mould sand is matched with the inner cavity surface of the functional sand core, so that the positioning and pressing of the built-in functional sand core are realized, and the stability of the sand core in the cavity is ensured; the improved built-in sand core not only has the functions of high-temperature radiation resistance and scouring resistance of the original technology precoated sand core, but also can not influence the positioning precision due to the removal of nonfunctional parts of the sand core, and ensures the dimensional precision grade of castings;

the non-functional part of the original technology coated sand core is removed, so that the weight of the coated sand core manufactured by the newly designed functional coated sand hot core box is only 9.5 kg, and the weight of the original technology coated sand core is 21.6 kg, and the single piece is reduced by 10.1 kg; the process overcomes the problem of double core making, double core setting and labor waste; meanwhile, the labor intensity of operators is reduced; more importantly, the core making efficiency is greatly improved; the molding core setting beat is shortened to some extent, the labor productivity is improved, and the molding reject ratio is reduced; the production cost is greatly reduced; the quality of the inner surface and the outer surface of the casting produced by the process is improved by one grade compared with the quality of the surface of the casting produced by the original process.

Compared with the casting process carried out by the traditional mould, the casting process carried out by the mould has the following advantages:

(1) The labor intensity of the core making process and the modeling process is reduced;

(2) Solves the problem of insufficient labor force of enterprises;

(3) The core making working efficiency is improved, and the output per shift is improved by 30%;

(4) The modeling efficiency is improved by 10%;

(5) The direct cost (manual and precoated sand) is saved by 426 yuan per ton, and the direct cost of 116.77 ten thousand yuan per year is saved by our company.

Drawings

FIG. 1 is a schematic view of a thermal core box according to an embodiment of the present invention;

FIG. 2 is a side view of FIG. 1;

FIG. 3 is a bottom view of FIG. 1;

FIG. 4 is a schematic view showing an assembly structure of a core box according to an embodiment of the present invention;

FIG. 5 is a schematic diagram showing a specific structure of a fixed mold of a core box in the embodiment of the invention;

FIG. 6 is a schematic diagram showing a specific structure of a moving die of a core box according to an embodiment of the present invention;

FIG. 7 is a schematic view of an upper plate mold according to an embodiment of the present invention;

FIG. 8 is a schematic diagram of a precoated sand core in an embodiment of the present invention;

FIG. 9 is a schematic representation of another embodiment of a precoated sand core;

FIG. 10 is a schematic illustration of a flywheel housing bottom casting employed in a prior art casting process;

FIG. 11 is a schematic diagram of functional surface structure of a precoated sand core working surface in the prior casting process;

FIG. 12 is a schematic illustration of a precoated sand core used in the inner cavity of a flywheel casing casting in the prior art casting process;

in the figure: the mold comprises a 1-movable mold supporting leg, a 2-hot core box movable mold, a 21-first positioning rod hole, a 22-first reset rod hole, a 3-hot core box fixed mold, a 31-positioning block, a 32-kidney-shaped positioning hole, a 33-second positioning rod hole, a 34-core shooting hole, a 35-second reset rod hole, a 4-hot core box heating pipe hole, a 5-upper plate mold, a 6-precoated sand core and 61-reinforcing ribs.

Detailed Description

Example 1

The embodiment provides a built-in functional tectorial membrane psammitolite casting mould of engine flywheel shell tide mould sand, as shown in fig. 1-9, the mould includes last template mould 5, lower template mould and gating system, be equipped with the last type piece that corresponds with last template mould on the last template mould, be equipped with the lower type piece that corresponds with lower template mould on the lower template mould, go up template mould 5 and lower template mould and form the die cavity through green sand molding involution, gating system and die cavity intercommunication are provided with the tectorial membrane psammitolite 6 with die cavity assorted that the hot core box made in the die cavity, wherein:

the hot core box comprises a hot core box fixed die 3 and a hot core box movable die 2 which are mutually involuted, and a cavity for forming a sand core with a built-in precoated sand for the flywheel shell damp mould sand of the automobile engine is formed between the hot core box fixed die 3 and the hot core box movable die 2, wherein:

a group of movable die supporting feet 1 are arranged on the movable die 2 of the hot core box, two first positioning rod holes 21 are symmetrically arranged on the surface of the movable die 2 of the hot core box, and four first reset rod holes 22 are uniformly distributed on the surface of the movable die 2 of the hot core box;

four corners of the hot core box fixed die 3 extend outwards to form positioning blocks 31, kidney-shaped positioning holes 32 are formed in the positioning blocks 31, two second positioning rod holes 33 matched with the first positioning rod holes 21 are symmetrically formed in the surface of the hot core box fixed die 3, a plurality of core shooting holes 34 are further formed in the surface of the hot core box fixed die 3, and four second reset rod holes 35 matched with the first reset rod holes 22 are uniformly distributed in corresponding positions on the surface of the hot core box fixed die 3;

the hot core box moving die 2 is oppositely arranged on the hot core box fixed die 3, the hot core box moving die 2 and the hot core box fixed die 3 are assembled and positioned through a positioning rod passing through a first positioning rod hole 21 and a second positioning rod hole 33, and hot core box heating pipe holes 4 for installing heating pipes are respectively formed in the side walls of the hot core box fixed die 3 and the hot core box moving die 2.

The casting process performed by using the engine flywheel housing damp mould sand built-in functional precoated sand core casting mould specifically comprises the following steps:

(1) Core making

A set of precoated sand core hot core box is processed according to the shape of a product to be cast, and a precoated sand core is manufactured by utilizing the hot core box and a core shooting machine, specifically comprising the following steps:

(a) The method comprises the steps of installing a hot core box fixed die on a fixed end of a core shooter, installing a hot core box movable die on a movable cylinder working plane of the core shooter, moving a movable cylinder head of the core shooter to the fixed end of the core shooter, driving the hot core box movable die to move to the hot core box fixed die, and realizing die assembly;

(b) The core shooter shoots sand from a core shooting hole into a cavity formed by mutually involuting a hot core box fixed die and a hot core box movable die, the sand shooting pressure is controlled to be 0.5-0.8Mpa, the sand shooting time is controlled to be 15-25 seconds, and a precoated sand core is preliminarily molded;

(c) Heating pipes are arranged in heating pipe holes of the hot core box on the side walls of the fixed die of the hot core box and the movable die of the hot core box, the hot core box is heated to 210-250 ℃, the curing time is controlled to 25-30 seconds, and the hot core box is cured and formed;

(d) After solidification and molding, the movable cylinder head of the core shooter moves in a direction away from the fixed end of the core shooter to drive the movable die of the hot core box and the fixed die of the hot core box to be separated, so that die opening is realized, and a molded precoated sand core is obtained;

(2) Modeling method

Manufacturing an upper template die and a lower template die according to the size of a flywheel casing casting, and correspondingly manufacturing a tide-die sand cavity according to the size of the upper template die and the lower template die with a matched sand box space, wherein the manufacturing method specifically comprises the following steps:

taking an upper plate mold, a lower plate mold and a matched sand box;

the sand box is arranged on the upper plate mould through a locating pin, damp mould sand is added, jolt-rammed and pressed, the upper plate mould and the sand box are separated, and a damp mould sand upper cavity is formed;

the sand box is arranged on the lower plate die through a locating pin, damp mould sand is added, jolt-ramming compaction is carried out, and the lower plate die and the sand box are separated to form a damp mould sand lower cavity;

placing the lower cavity of the wet sand into a horizontal state, placing the manufactured precoated sand core into the lower cavity of the wet sand, and then combining the upper cavity of the wet sand taking the sand box as a carrier with the lower cavity of the wet sand taking the sand box as a carrier by using a combining locating pin as a reference to form a molding cavity;

(3) Locking the upper and lower cavities of the combined wet sand by using a box clamp;

(4) Smelting and casting

Placing the casting mould in a casting area, smelting raw materials, injecting molten iron into the casting mould through a casting system, casting for molding, cooling, and separating out sand;

(5) Polishing

And (3) after casting molding, taking out the casting, and performing shot blasting and polishing treatment on the casting to obtain the casting.

In the embodiment, the upper template mold designs a concave-convex matched curve surface according to the external shape of the precoated sand core; the core holes 34 are two groups, each group of core holes is surrounded by 8 independent core holes to form a circle, and the circles surrounded by the two groups of core holes are concentric; the heat core box is internally provided with reinforcing ribs 61 at the easily deformable portions of the cast product.

The thickness of the thinnest part of the wall thickness of the precoated sand core processed by the hot core box is 12mm; 6-8 reinforcing ribs are arranged in the precoated sand core, and the height of each reinforcing rib is 10mm.

According to the design scheme, the nonfunctional surface part of the built-in precoated sand is removed to the maximum extent, and in order to realize the functional sand core of the precoated sand, a set of precoated sand hot core box is redesigned; referring to fig. 5 and 6, a set of precoated sand hot core boxes redesigned by us are used for manufacturing a precoated sand functionalized precoated sand core; see fig. 8-9; the thickness of the thinnest part of the improved precoated sand core is designed to be 12mm; the height of the inner land root reinforcing rib is 10mm; see fig. 9; the removed part is replaced by damp mould sand; the original process mould flat cover box is redesigned into a wet mould sand hanging sand, and the figure 7 is used for replacing a non-functional precoated sand core external mould, and the hanging sand surface of a formed upper cavity of the wet mould sand is matched with the inner cavity surface of the functional sand core, so that the positioning and pressing of the built-in functional sand core are realized, and the stability of the sand core in the cavity is ensured; the improved built-in sand core not only has the functions of high-temperature radiation resistance and scouring resistance of the original technology precoated sand core, but also can not influence the positioning precision due to the removal of nonfunctional parts of the sand core, and ensures the dimensional precision grade of castings;

the non-functional part of the original technology coated sand core is removed, so that the weight of the coated sand core manufactured by the newly designed functional coated sand hot core box is only 9.5 kg, and the weight of the original technology coated sand core is 21.6 kg, and the single piece is reduced by 10.1 kg; the process overcomes the problem of double core making, double core setting and labor waste; meanwhile, the labor intensity of operators is reduced; more importantly, the core making efficiency is greatly improved; the molding core setting beat is shortened to some extent, the labor productivity is improved, and the molding reject ratio is reduced; the production cost is greatly reduced; the quality of the inner surface and the outer surface of the casting produced by the process is improved by one grade compared with the quality of the surface of the casting produced by the original process.

In addition to the embodiments described above, other embodiments of the invention are possible. All technical schemes formed by equivalent substitution or equivalent transformation fall within the protection scope of the invention.

Claims (4)

1. The utility model provides an engine flywheel shell tide mould sand embeds functional tectorial membrane psammitolite casting mould, this mould includes last template mould (5), lower template mould and gating system, its characterized in that: the utility model discloses a mould, including mould, hot core box, mould, pouring system, lower mould, mould (5) are equipped with the last type piece that corresponds with last mould on last mould (5), be equipped with the lower type piece that corresponds with lower mould on the lower mould, go up mould (5) and lower mould and form the die cavity through wet sand molding involution, pouring system and die cavity intercommunication, be provided with hot core box made in the die cavity with die cavity assorted tectorial membrane psammitolite (6), wherein:

the hot core box comprises a hot core box fixed die (3) and a hot core box movable die (2) which are mutually matched, a cavity for forming a sand core of a built-in precoated sand of a flywheel shell of a formed automobile engine is formed between the hot core box fixed die (3) and the hot core box movable die (2), and a reinforcing rib (61) is arranged in the hot core box, wherein:

a group of movable die supporting feet (1) are arranged on the movable die (2) of the hot core box, two first positioning rod holes (21) are symmetrically arranged on the surface of the movable die (2) of the hot core box, and four first reset rod holes (22) are uniformly distributed on the surface of the movable die (2) of the hot core box;

the four corners of the hot core box fixed die (3) are respectively extended outwards to form positioning blocks (31), kidney-shaped positioning holes (32) are formed in the positioning blocks (31), two second positioning rod holes (33) matched with the first positioning rod holes (21) are symmetrically formed in the surface of the hot core box fixed die (3), a plurality of core shooting holes (34) are further formed in the surface of the hot core box fixed die (3), the two groups of core shooting holes (34) are respectively formed by encircling 8 independent core shooting holes, the circles encircled by the two groups of core shooting holes are concentric, and four second reset rod holes (35) matched with the first reset rod holes (22) are uniformly distributed on the corresponding positions of the surface of the hot core box fixed die (3).

The hot core box moving die (2) is oppositely arranged on the hot core box fixed die (3), the hot core box moving die (2) and the hot core box fixed die (3) are assembled and positioned by penetrating through a first positioning rod hole (21) and a second positioning rod hole (33) through positioning rods, and hot core box heating tube holes (4) for installing heating tubes are further formed in the side walls of the hot core box fixed die (3) and the hot core box moving die (2) respectively.

2. The engine flywheel housing wet mold sand built-in functional precoated sand core casting mold of claim 1, wherein: the upper template mold designs a concave-convex matched curve surface according to the external shape of the precoated sand core.

3. The engine flywheel housing wet mold sand built-in functional precoated sand core casting mold of claim 1, wherein: the thickness of the thinnest part of the wall thickness of the precoated sand core is 12mm.

4. The engine flywheel housing wet mold sand built-in functional precoated sand core casting mold of claim 1, wherein: 6-8 reinforcing ribs are arranged in the precoated sand core, and the height of each reinforcing rib is 10mm.