EP2323783A1 - Core or foundry sand coated and/or mixed with water glass, having a water content in the range of > approximately 0.25 wt.% to approximately 0.9 wt.% - Google Patents

Abstract

The present invention relates to a core or foundry sand that can be used for producing cores and casting molds for casting metal melts, comprising a foundry base material, coated with a layer of a bonding agent and a layer of water glass arranged on top, and having a water glass content in the range of > approximately 0.25 wt.% to approximately 0.9 wt.% relative to the total weight of the core and foundry sand.

Description

 Water glass coated and / or mixed core or foundry sand having a water content in the range of> about 0.25% to about 0.9% by weight.

The invention relates to a core or molding sand for the production of cores and

Casting molds for casting molten metal, which comprises a molding base material (for example quartz sand, chrome ore sand, zircon sand, olivine sand, synthetic sands), the

Water glass and wherein the core or molding sand has a water content in the range of> about 0.25 wt .-% to about 0.9 wt .-%, based on the total weight of the core and

Formsands, has. Furthermore, the invention relates to a method for producing such a core or foundry sand as well as a method for producing a core or a casting mold with this core or molding sand and its use.

Core or molding sands for the production of cores or other casting molds are known. Usually, these are first brought into the desired shape by a casting mold forming tool, such as a core tool, with the core or molding sand and then the core or molding sand is compacted and cured. After opening the tool, the desired molding, such as a casting core, can be removed. Using this casting core, metal melts, including aluminum alloy melts, can then be poured into the desired shape. After the molten metal has solidified, the casting core or the casting mold can be removed, for example by means of shaking. By shaking the previously solid and stable Gießkern- / form disintegrates. A known process for the production of core or foundry sand is also called "croning process" according to its inventor, in which a fine-grained quartz sand is used as mold base, in which each sand grain is coated with a thermoplastic phenolic resin layer state solid at room temperature. If the core or foundry sand now in an a molding cavity forming, such as a the mold imaging tool, for example a Kemwerkzeug introduced and heated to 250 ⁰ C to 300 ⁰ C, to melt the binder film and make it through to Polycondensation Binder bridges that are solid after completion of the polycondensation reaction and have thermosetting properties The finished core or the finished form can be removed from the tool The core or molding sand used in the croning process has the advantage over the other common core / mastering processes (eg cold box, hot box, furan Resin, water glass CC * method) that the curing reaction, in contrast to the aforementioned method not directly after mixing, but only after renewed heat supply (250 ° C-300 ° C) begins. The shelf life of the ready-mixed core or foundry sand is virtually unlimited when properly stored. During processing, the core or molding sand exhibits good flowability, good image accuracy, high dimensional accuracy, high edge sharpness and high surface quality. A disadvantage of the croning process, however, is that the tool temperature for the production of the cores or the Foπnteile from the core or molding sand must be extremely high, causing a high energy demand. In the subsequent casting with a molten metal at about 700 ⁰ C-1700 ⁰ C using cores or Foπnteilen produced by the Croning process, the phenolic resin burns, releasing Harmful and polluting emissions (eg mono- and polycyclic aromatics). The disposal of the used core or molded parts after casting is an environmental problem, since they can be deposited only with high financial cost (hazardous waste landfill). Even a possible thermal regeneration is associated with extremely high costs and environmental pollution.

In order to avoid the environmental problems, it is also known to use a molding material with an inorganic, for example. Water glass-based binder. The Fomignmdstoff is mixed with an aqueous solution of water glass and immediately anschießend injected into a mold. For solidification of the core or molding sand to a molding heat can be supplied to solidify by dehydration, the core or molding sand (physical hardening).

In another method, the core or molding sand will be gassed with CQ to chemically cure the molded article.

Thus, for example, from DE 103 21 106 a method for producing a molding for casting molds is known, in which case a core or molding sand is used, which is produced on the basis of quartz-free sand and an inorganic binder produced by water glass. In this case, a mixture of a water glass binder and a molding material is mixed and this is filled directly into a mold.

Also known from DE 196 32 293 a method for producing Kemformlingen for foundry technology, in which case filled a mixture of an inorganic refractory molding sand and an inorganic binder based on water glass in a Kemkasten and then withdrawn to solidify the core, the water or CO ₂ is fumigated.

A waterglass-based binder system which can be used in these processes is described in DE 199 51 622. This consists of an aqueous alkali silicate solution, wherein it additionally contains a hygroscopic base. The solids content of the alkali metal silicate solutions used is described as 20 to 40%.

Furthermore, EP 0 917 499 discloses a process for producing core moldings for the foundry industry, in which a mixture of an inorganic refractory molding sand and a waterglass-based inorganic binder is used under certain conditions to form the core. In addition, EP 0 917 499 describes a process for the production of a circulating core sand, consisting of residues of old skins of core moldings. This means that this sand has passed through the casting process at least once, i. the cores were poured off, gutted and then singled out.

It is thus common to all conventional processes using an inorganic binder that an aqueous alkali metal silicate solution is mixed with a molding material and then this moist mixture is introduced directly into a molding tool. A disadvantage of this method is that after mixing the molding base material and the aqueous alkali silicate solution obtained is not storage-stable or is only partially storable, as in a closed Foπnstofϊbehälter. This means that the mixture must be prepared immediately before the production of the molding and then used immediately. Moreover, it is disadvantageous that the core or molding sand of FormgrundstofF and an aqueous alkali metal silicate solution is limited trickle and therefore additional measures must be taken to ensure that the core or molding sand fills all the cavities of a mold, such as by applying negative pressure or Shaking the mold. The core circulation sand described in EP 0 917 499 is also unsuitable for obtaining a storage stability combined with good properties in the production of a core molding, since the circulation core sand can not be used directly for the production of core moldings.

The present invention is therefore based on the object to provide a core or molding sand available, which overcomes the disadvantages of the conventional Kem- or molding sand and in particular to provide a core or molding sand available, which is storage stable and immediately, without further Steps can be used to manufacture a molded article without health or environmental risks associated with its use. Furthermore, the core or molding sand should allow easy and safe filling into a mold.

To solve the problem, a core or molding sand for cores and casting molds for casting molten metal is provided, which comprises a molding material, which with

Water glass is coated or mixed and has a water content in the range of> about 0.25

Wt .-% to about 0.9 wt .-%, based on the total weight of Kem- and molding sand has.

The water content is understood to include the upper and lower values of the region (s). In addition, a method for producing a core or molding sand according to the invention is provided and a method for producing a core and a

Casting mold for casting molten metal using the invention

Core or molding sand.

The waterglass used according to the invention preferably has a dynamic viscosity of> 10 ² Pa * s, more preferably> 10 ² " ⁵ Pa * s, in particular of> 10 ³ Pa * s. Waterglass with a dynamic viscosity of> 10 ² Pa * s is solid This means that the core or foundry sand according to the invention is coated or mixed in particular with solid water glass.

In addition, the core and foundry sand according to the invention has a water content in the range of> about 0.25 wt .-% to about 0.9 wt .-%, based on the total weight of the core and foundry sand, preferably from about> about 0.3 Wt .-% to about 0.9 wt .-%, in particular from> about 0.3 wt .-% to about 0.9 wt .-%, based on the total weight of Kem- and molding sand. If the water content of the core and molding sand is less than about 0.25 wt .-%, based on the total weight of the core and molding sand, then no core and molding sand is obtained, which can be used immediately, in particular no core and molding sand which would be useful in the inventive method of making a core and mold described below. If the water content is above about 0.9 wt .-%, then no storage-stable core or molding sand is obtained. Of the Water content is determined according to the VDG leaflet "Testing of clay-bound molded materials Determination of water content" P 32, Section 4.1., April 1997.

The term "coated" as used in the context of the present invention means that the individual particles of the molding material are substantially uniformly coated by a waterglass coating, but the term is not to be understood as meaning that each individual particle of the molding material is separate from one another must be coated with a water glass coating, but also includes embodiments in which particles are only partially coated or even several particles are coated together by a water glass coating.

The term "mixed", as used in the context of the present invention, means that the water glass is firmly mixed (homogenized) with the molding base material.

The core or molding sand according to the invention is characterized in that it is dry and free-flowing.

The determination of the flowability is carried out, for example, with measuring funnels or special pourability testing devices, such as from the company Karg Industrietechnik, wherein the trickle time at a given mass or volume is measured as a comparison indicator and given in seconds.

For example, the core and foundry sand according to the invention preferably has a flowability of <about 4 s, more preferably <about 3.5 s, measured at a sample amount of 35Og in a measuring funnel with an inner diameter at the upper, wide edge of 90 mm and a funnel height of a total of 95 mm and a length of 32 mm and an inner diameter of the spout of 15 mm at room temperature of about 20 ⁰ C.

Preferably, the waterglass coated or blended with the mold base comprises additional additives selected from the group consisting of adhesion modifiers, flow improvers, casting surface improvers, and release agents. The additive is preferably selected from the group consisting of caustic soda, amorphous SiO 2, graphite, silicone oil emulsion, stearates, various oils, surfactants, aluminum oxides, iron oxides, talc, boron nitrides, magnesium oxide and various metal oxides.

The adhesion promoter is preferably selected from sodium hydroxide solution, hygroscopic bases and / or surfactants. The flow improvers used are preferably additives selected from the group consisting of amorphous SiO 2, graphite, silicone oil, silicone oil emulsion, stearates, various oils and surfactants. As the improving agent for the casting surface, there are preferably additives selected from the group consisting of amorphous SiO ₂ , graphite, aluminum oxides, iron oxides. Talc, boronitrides, magnesium oxide and various metal oxides used. The release agents used are preferably additives selected from the group consisting of silicone oil, silicone oil emulsion, aluminum oxides, iron oxides, talc, graphite and boron nitride. The drying agent and / or flow aid used is preferably dry, amorphous SiO 2. The molding material used is preferably a refractory mineral or synthetic sand, in particular quartz sand, zircon sand, chrome ore sand, almost spherical sand, olivine sand or mixtures thereof. The molding material preferably has a mean particle size of about 0.08 mm to 0.6 mm, in particular from 0.08 mm to 0.5 mm. Furthermore, further adjuvants can be added to the coated core or foundry sand according to the invention, such as flow aids, drying agents, flow improvers, improvers for the casting surface and / or release agents. The other auxiliaries are preferably selected from the group consisting of dry amorphous SiO ₂ , aluminum oxides, iron oxides, talc, graphite and boron nitrides. The properties of the other adjuvants are as described above with respect to their addition to the waterglass coating.

Preferably, a total amount of additives (without water glass) of up to 4 wt .-%, in particular up to 3 wt .-%, based on the total weight of the core or foundry sand added. In particular, the molding sand according to the invention preferably does not comprise any organic additives or additives.

The core or foundry sand according to the invention is preferably produced in a process comprising the following steps: a) a molding base material according to the invention is provided, b) an aqueous solution of waterglass and / or dry waterglass powder is added and c) the core or molding sand is formed mixed, dried and mixed.

For this purpose, in step a), a mixer is preferably initially filled with the molding base material, which ensures the homogenization of the core or molding sand with the binder components and optionally the additives. As mixers, preference is given to using wing mixers, oscillating mixers, intensive mixers, vortex mixers or vertical rolling gears. In step b), an aqueous solution of water glass and / or dry / solid water glass and optionally further additives may then be added. If an aqueous solution is used, it preferably has a dynamic viscosity of up to 10 ² Pa * s. Thus, the term "aqueous solution" encompasses both viscous, viscous and pasty waterglasses.When a dry / solid waterglass is added, it preferably has a dynamic viscosity of more than 10 ² Pa * s. It is also possible to use a mixture of various water glasses and / or a mixture of an aqueous solution of waterglass and dry / solid waterglass Preferably, the waterglass used is an alkali silicate solution of the general composition xSiCh "yM ^ O ^* nHjO, where M is selected from Li ^* , K ^* or Na ^{^} and x: y is preferably about 1: 1 to 4: 1, especially about 2: 1 to 3.5: I is from ₅ (where the ratio x: y as a module of the water glass, ie, the ratio SIOO: M ₂ O is ). The index n then determines the amount of HiO in the solution. Further, an aqueous solution of alkali silicate having a solid content of not more than about 60% by weight based on the entire solution is preferably used. Preferably, about 0.5 to about 8 wt .-% based on the weight of the molding material of the water glass, added. In addition, a primer may preferably be added in an amount of up to about 0.5% by weight, preferably about 0.1 to about 0.2% by weight, based on the weight of the masterbatch. The adhesion promoter is preferably an aqueous solution of sodium hydroxide solution, in particular about 10 to about 50%, particularly preferably a 30% strength sodium hydroxide solution. Particularly preferably, the adhesion promoter is added to the molding material in step b) before the addition of the aqueous solution of water glass.

Preferably, the aqueous solution of water glass is then added to the addition of the adhesion promoter. As a result of this sequence of addition of adhesion promoter and aqueous solution of waterglass, in the core or molding sand according to the invention a layer structure comprising at least two layers is achieved, in which the first, inner layer is formed by the adhesion promoter and the second layer by the water glass becomes. It is also possible that further layers are applied. These may be applied below the adhesion promoter layer, between the adhesion promoter layer and the water glass layer and / or on the water glass layer. In the course of manufacture, such a layer structure can be controlled by the order of addition of the layer-forming materials during the mixing process. As layer-forming materials, for example, the aforementioned additives and / or auxiliaries are used. The formation of a separate adhesion promoter layer and a layer of water glass located thereon leads to a more stable coating of the core or molding sand with water glass, which, inter alia, relieves the mechanical stresses during the production process, in particular by the wing mixers, vibratory mixers, Intensive mixer, vortex mixer or vertical bunker can better resist.

Then, preferably, a flow improver or casting surface improver is preferably added in amounts up to about 3% by weight based on the weight of the masterbatch. Particularly preferred is first an aqueous suspension of amorphous SiO. preferably in an amount of up to about 3% by weight, in particular about 0.6 to about 1.0% by weight, based on the weight of the masterbatch, and then preferably an aqueous suspension of amorphous SiO 2 and graphite, preferably in one Amount of up to about 3 wt .-%, in particular about 0.6 to about 1.0 wt .-%, based on the weight of the mold base, added thereto. The aqueous suspension is preferably about 10 to about 80%, in particular about 30 to about 60% pure. Finally, in step b), a flow improver and / or release agent is preferably added in an amount of up to about 1% by weight, in particular up to about 0.8% by weight, based on the weight of the molding base material Silicone oil and / or a silicone oil emulsion.

In addition, it is also possible to dispense with the addition of all additives, so that the mixture consists only of the molding material and the water glass.

In a particularly preferred embodiment, step b) is carried out by first an adhesion promoter, preferably sodium hydroxide solution, then the binder, namely the optionally aqueous solution of waterglass, then a flow improver and / or improver for the casting surface, particularly preferably an aqueous suspension of amorphous SiCh and then adding amorphous StO ₂ and graphite followed by the addition of a flow improver and / or release agent, particularly silicone oil or a silicone oil emulsion. In particular, after the addition of each individual component, the mixture is homogenized by means of the mixer. In an alternative embodiment, after addition of all components, the mixture is homogenized by means of the mixer.

In another preferred embodiment, dry / solid water glass or a mixture of aqueous and dry / solid water glass can already be added in step b), whereby it is not necessary in the case of the addition of dry / solid water glass to dry the mixture. In this embodiment, the mixing of the production of the most uniform mixture is used.

In step c), the core or molding sand is then dried. For drying, the friction energy introduced into the mixture by the mixer is preferably used. For this purpose, it is particularly preferred to use a wing mixer which has a rotational speed of 160 rpm and it is preferably mixed for a long time. By heating under constant Venvirbelung the mixture is deprived of water. According to the invention, the water content of the waterglass with which the masterbatch is coated or mixed by mixing and dehydration is adjusted to a level in the range of from about 0.25% to about 0.9% by weight. As a result, a core or molding sand is obtained, which is provided with a solid coating of water glass. The molding material which is obtained by the process according to the invention is thus coated with water glass, at the same time a free-flowing core or molding sand is obtained, which is also storage stable.

The drying can be carried out with any device as long as it is ensured that the water content of the water glass coating of the molding base material is maintained. An external heating, hot air, radiant heating, vacuum, or negative pressure or a heating jacket can preferably also be used for this purpose.

After mixing, other auxiliaries can be added to the core or molding sand, such as flow aids, drying agents, flow improvers, improvers for the cast surface or release agents. Preferably, each adjuvant will contain an amount of up to about 2% by weight, based on the weight of the masterbatch.

Preferably, at least one further additive selected from the group consisting of adhesion promoters, flow improvers, casting surface improvers and release agents may be added to the masterbatch before step c). In addition, at least one further adjuvant selected from the group consisting of flow aids, drying agents, flow improvers, casting surface improvers and release agents may preferably be added to the core or molding sand after step c).

Preferably, the core or molding sand thus obtained can then be screened for the deposition of agglomerates. The resulting core or foundry sand according to the invention can then be used directly to produce a core or a molded part. However, the core or foundry sand according to the invention can also be stored loose or packed and can be stored almost indefinitely because of its consistency. Thus, the core or foundry sand according to the invention can be prepared separately from a method for producing the molded part and stored, packaged or transported, which means a considerable work and time savings for the foundries and the manufacturer of core and moldings.

In particular, the core and foundry sand according to the invention preferably does not comprise any organic additives or additives, so that no environmentally harmful substances are formed when it is used. The core or foundry sand according to the invention is then advantageously used in a method for producing a casting mold or a core or core molding for casting molten metal. For this purpose, first a core or molding sand according to the invention is provided for the core production a) and b) a core tool or tool is filled with the core or molding sand according to the invention. The filling can eg be carried out by trickling, blowing and / or shooting with a carrier medium such as compressed air, hot air or steam. This can be done by means of a commercially available core shooting machine or by suction and subsequent blowing. Preferably, the core or molding sand is then compressed in the core tool. For hardening and solidifying the core or molding sand to form the core, c) the core or molding sand in the tool is brought into contact with at least one hardening agent, preferably water, water-containing liquids and / or chemical hardening agents such as CO ₂ . Preferably, steam is used for this purpose. The water vapor is preferably introduced into the tool. The water vapor can be introduced into the molding material, for example, by means of a gassing plate via the injections and / or through the steam connection to the tool vents. Particularly preferred is a water vapor-air mixture is used, which preferably contains an amount of water to about 6 wt .-% based on the mold base, in particular 3-4 wt .-%. The pressure is preferably up to about 10 bar, in particular about 0.5 to about 1.5 bar. For producing a casting mold or a core or core molding, the core or molding sand according to the invention is thus brought into a core tool or molding tool, preferably by firing or pouring, and then preferably compacted. The compaction is preferably carried out by shaking and pressing. For hardening and solidifying the core or molding sand to form the core, the core or molding sand in the tool is preferably brought into contact with an aqueous solution or water. Preferably, steam is used for this purpose. The contacting with water, in particular water vapor, can preferably be carried out during step b), for example, in a temporal relationship with the filling, in particular the shooting of the core or molding sand, or after its filling in a separate step c). By contacting with water, the waterglass coating of the core or foundry sand according to the invention is dissolved and softened. By softening the waterglass coating, binder bridges form between the particles of the core or foundry sand.

Subsequently, preferably the core is solidified, in particular by removing the water or by chemical means. This can preferably be achieved in that in

Connecting energy, in the form of a heat transfer medium, such as in the form of hot air or a water vapor-air mixture, which is passed through the core, is introduced into the core. In another Ausruhrungsform the water can be removed by a

Vacuum is applied to the tool. By removing the water, the water glass solidifies and it is a stable, solid molding obtained. It is thus a substantially physical process without the need for additional chemical reactions.

In an alternative embodiment, however, the curing agent CO; be used and the solidification is thus carried out essentially chemically. In a further embodiment, both methods for solidification can be carried out either simultaneously or also successively. After hardening or solidifying (drying) the molding, the tool can be opened and the finished molding, for example. A core removed.

In another embodiment, the core within the core tool can only be preconsolidated, for example pre-dried, until the core has sufficient strength to be removed from the core tool. Thereafter, the preconsolidated core may be further solidified outside the core tool, in particular, the predried core may be finish dried in, for example, a microwave, an oven, or a drying chamber.

In a preferred embodiment, the tool for forming the core or molding during all steps b) to c) to a temperature of from room temperature or about 20 ⁰ C to about 200 ⁰ C, more preferably about 70 ⁰ C to about 160 ⁰ C, heated in particular about 70 to about 120 ⁰ C. In addition, it is possible to carry out the contacting of the molding with water, preferably with water vapor, in temporal relation to the lulling of the core or molding sand in the cavity forming the molding, as already described above. This advantageously ensures that when using steam no liquid water is formed in the tool or condenses on the tool. In addition, immediately after filling and contacting the core or molding sand with water, the water can then be withdrawn, for example, by the tool being heated to said temperatures. In addition, the water may additionally or alternatively be withdrawn using hot air and / or warm carrier gas and / or by applying a negative pressure / vacuum. The duration of contact with water may be carried out, for example, for about 5 minutes to about 3 hours.

In the above, the method is preferably described with a sequence of steps a) to c). However, another sequence of steps is possible and within the meaning of this invention.

The core or mold of the present invention preferably has a flexural strength of at least about 300 N / cm ² , more preferably at least about 400 N / cm ^2, and most preferably at least about 450 N / cm ² . The flexural strength of the core is tested in accordance with the VDG leaflet P 72 "Binder Testing, Testing of Cold-curing Resin-Bonded Wet Forming Materials with Addition of Hardening" dated October 1999.

Such a manufactured core according to the invention can then be used to produce a casting mold for casting molten metal.

The method according to the invention and the molding sand according to the invention have the advantage that the molding sand according to the invention has a similar effect due to its free-flowing properties

Shooting behavior, such as the core or molding sand used in the above-described croning process and thus reliably without additional steps in a mold or

Kemwerkzeug can be introduced. In contrast to the croning process, however, the process of the invention can be carried out by purely physical steps for solidification of the molded part, wherein no environmentally harmful substances are formed become. This is advantageous because when pouring the liquid metal no elaborate extraction systems must be kept in the foundry and the employees are exposed to no hazardous gases such as phenolic compounds. The recycling and disposal of the used inorganic core or foundry sand are easily possible. During the process according to the invention, in contrast to the croning process, significantly lower temperatures can be used for solidification, which leads to considerable energy savings. In addition, it has been found to be advantageous that when using the inorganically bonded cores in chill casting condensation products in the mold are significantly reduced. This results in a lower cleaning costs of the mold after casting and thus a higher mold availability, whereby an increase in productivity can be achieved. With the method according to the invention molded parts can be produced, which have a good imaging accuracy and high edge sharpness.

Furthermore, the invention relates to a core tool or molding tool for producing a core molding or a casting mold. The core tool is provided according to conventional core tools suitable for making a casting mold, wherein at least one port suitable for introducing a curing agent such as water vapor or a chemical curing agent is provided. Optionally, further openings may be provided in the core tool from which the curing agent, such as the water vapor or chemical curing agent, may again escape. In particular, the core tool comprises a suitable mold for producing the desired Keraformlings or casting mold and at least one connection for introducing or shooting the core and molding sand, and at least one connection for the introduction of a curing agent, such as water vapor or a chemical curing agent. However, the terminals may also be provided together in one terminal, i. a connector which is suitable both for injecting the core and molding sand and the curing agent, such as water and / or the chemical curing agent. The connection may also be a gassing plate, at the same time the injections and / or a separate steam connection to the tool vents. The core tool is preferably designed in two parts in order to simply remove the core filler or the casting mold after production.

The invention will now be illustrated by way of examples.

Example 1:

Production of core or molding sand: Binding:

FoπngTundstoff: quartz sand H32

1. Primer: 0, 1 wt .-% NaOH

2. Binder: 3.0% by weight of water glass {modulus 2.5; 48% solids)

3. Flow improver / 0.8 wt .-% suspension of amorphous SiO and Improuπgsmittel water (50%) for the casting surface

4. Rieselhilfe 0.5 wt .-% amorphous SiO ₂

(The quantities are based on the mass of the molding material used)

Mixing unit:

Mixer type: Wing mixer

Speed: 160 ^u / _miπ

Mixing time: Ih

The required heat energy was completely introduced by the resulting friction energy. Alternatively, the mixing time could be through the use of another

Mixing unit or an external heat source, or a negative pressure can be significantly reduced.

The agglomerates were separated using a sieve with a mesh size of

1 mm. A comparative measurement of the flowability of the foundry sand produced in Example 1 with various other core and form sands is shown in Table 1: Comparative measurement with a free-flow tester from Karg Industrietechnik: 350g sand each, spout 015mm

Table 1

As can be seen from the table, the core or foundry sand produced according to Example 1 has the same good flowability as a Croning produced and is superior to the other conventional Kemsanden.

Core Production: Tool Parameters:

Core: Bending bar (2pcs)

(Dimensions: 22.5mm x 22.5mm x 185mm)

Mold temperature: 8O ⁰ C Application of molding sand: pouring

Temperature water vapor / air mixture:> 105 ^c C Pressure of water vapor / air mixture: 1 bar

Amount of water in steam-air mixture: 13mL Duration: 30s

Hot air drying:

Hot air temperature: 160 ⁰ C

Fumigation pressure: 1 bar

Duration: 30s

Average core weight: 137g

Example 2:

Comparative tests between a water-glass-coated molding material according to the invention and a circulating core sand

For the experiments the in Example} were given as well as the following further molding material mixtures used:

• Water glass coated molding material

H32 + 0, 1% additive A + 5.0% water glass binder (modulus 2.5) + 0.8% additive C

• Circumferential rim (thermally and mechanically loaded)

H32 + 0.1% additive A + 5.0% water glass binder (module 2.5) flowability

The determination of the flowability was carried out at a sample size of 350 g in a measuring funnel with an inner diameter at its upper, wide edge of 90 mm and funnel height of 95 mm in total and 32 mm in length and 15 mm in inner diameter of the outflow tube at room temperature of about 20 ⁰ C measured.

Results:

• Croning molding material trickling time: 2.9s; 3.0s; 3, 1 s => 3.0 s (100%)

• Water-glass coated molding material trickling time: 3.3s; 3,4S; 3.2s => 3.3s (90%)

• H32 new sand trickle time: 3.6s: 3.5s; 3.5s => 3.5s (82%)

• Circulating edge sanding time: 3.7s; 3.5s: 3.6s => 3.6s (80%)

It emerges from the experiments that the flowability of the peripheral edge of the sand is significantly worse than that of the coated molding material according to the invention.

Water or moisture content (refer to the molding material)

Oven temp .: 105 ^° C; to constant weight according to VDG leaflet P32 section 4.1 of April 1997

The water glass coated FormstofT after the manufacturing process still has a water content or moisture content (based on the molding material weight) of 0.38%.

The circulating core sand (thermally and mechanically loaded) only has a moisture content of 0.18%.

Bending strength:

To determine the flexural strength, experimental sketches (test bars) were prepared from both foam mixtures and the flexural strength was measured.

Test Parameters:

Tool temperature 6O ⁰ C

Fumigation pressure (water vapor): I, I bar

Begasungsdauer (water vapor): 60s drying by means of negative pressure The result was that the waterglass-coated molding material according to the invention had an average bending strength of 481 N / cm ² , while the circulating core sand was not bindable and it could not be made cores.

A production of cores by the introduction of water vapor is thus not possible with the Umlaufkemsand, and it could be achieved no bond.

Claims

1. Core or foundry sand usable for the production of cores and casting molds for

5 Pouring of molten metal, comprising a mold base, coated with a layer of an adhesion promoter and an overlying layer of water glass and a water glass content in the range of> about 0.25 wt.% To about 0.9 wt.% Based on the total weight of the core and molding sand. The core or foundry sand of claim 1, wherein the waterglass additionally comprises at least one further additive selected from the group consisting of flow improvers, casting surface improvers, desiccants, and release agents. 5

A core or foundry sand according to any one of the preceding claims wherein the molding base is selected from the group consisting of mineral and synthetic sands such as quartz sand, chrome ore sand, zircon sand, near spherical sands and olivine sand. 0

4. Core or foundry sand according to any of the preceding claims, wherein the foundry stock has an average grain size of from about 0.08 mm to about 0.5 mm.

5. A process for producing a core or molding sand according to any one of the preceding claims, comprising the steps of 5 a) providing a molding material b) adding a coupling agent and then adding water glass, and 0 c) drying of the core or molding sand, so that Water content in the range of> about 0.25 wt.% To about 0.9 wt.% Based on the total weight of the core and foundry sand. 5

6. The method of claim 5, wherein the resulting mixture is homogenized after each addition step.

7. The method according to any one of claims 5 or 6, wherein step c) by the input of ^ friction energy during mixing or additional heat input, preferably by means of

Hot air, radiant heating, heating jacket, or by applying vacuum or negative pressure is performed. 8. The method according to any one of claims 5 to 7, wherein step c) is carried out at a temperature of from room temperature to 160 ° C and for a period of time depending on the mass of 5 min to 3 h.

9. The method according to any one of claims 5 to 8, wherein the core or molding sand after step c) is screened.

10. core or foundry sand for moldings of a casting mold for casting molten metal, obtainable by a method according to one of claims 5 to 9.

W, method for producing a molded part of a casting mold for casting molten metal, comprising a) providing a core or molding sand according to any one of claims 1 to 4, b) filling the core or molding sand in a mold cavity, c) in contact bring the core or foundry sand with at least one curing agent before, during and / or after the filling in step b) and solidifying the Foπnteils.

12. The method of claim 1 1, wherein step c) is carried out by bringing into contact with water vapor.

13. The method according to any one of claims 11 or 12, wherein step b) and c) are carried out simultaneously.

14. The method according to any one of claims 11 to 13, wherein during at least one of steps b) to c) of the molding cavity imaging to a temperature in the range of about 20 ⁰ C to about 160 ⁰ C, in particular 60 to 120 ⁰ C, is heated.

15. The method of claim 14, wherein the molding imaging cavity during all steps b) to c) is heated.

16 molded part of a casting mold for casting molten metals, obtainable by a method according to any one of claims I l to 15. IT _^ Use of a core or molding sand according to any one of claims 1 to 4 for producing a molded part of a casting mold for casting molten metal.

18, core tool suitable for producing a molded part of a casting mold for casting molten metal, comprising at least one casting mold with at least one connection for introducing the core or molding sand and at least one connection for the introduction of a curing agent, optionally in the form of water vapor, or at least one Connection which is suitable both for the introduction of the core or molding sand and the introduction of a curing agent.