CN107805737B - Preparation method of dezincification-resistant lead-free low-silicon extruded arsenic brass rod - Google Patents

Abstract

The invention relates to the field of copper alloys for kitchen and bathroom industry, and provides a preparation method of an anti-dezincification lead-free low-silicon extrusion arsenic brass rod with good dezincification corrosion resistance, high strength and good processing performance, which comprises the steps of smelting the following raw materials of Cu 62-65% by mass, Si 0.6-1.0% by mass, As0.07-0.12% by mass, Al 0.5-0.8% by mass, Fe 0.03-0.1% by mass, Pb < 0.1% by mass, and the balance of Zn and impurities with the total amount not more than 0.35% by mass, and then obtaining a solid brass rod through casting and extrusion processes.

Description

Preparation method of dezincification-resistant lead-free low-silicon extruded arsenic brass rod

Technical Field

The invention relates to the field of copper alloys for kitchen and bathroom industry, in particular to a preparation method of an anti-dezincification lead-free low-silicon extrusion arsenic brass rod.

Background

Lead-free brass is a brass alloy material that is currently preferred for widespread use in the kitchen industry, replacing lead brass, but to date only bismuth brass and silicon brass have found a small range of marketable applications. The cost of silicon is significantly lower than other elements that replace lead. The silicon brass has good mechanical property, corrosion resistance superior to common brass, no corrosion cracking tendency, good wear resistance, good pressure processability in cold state and hot state, easy welding and brazing, good machinability, and the heat conductivity and the electric conductivity of the silicon brass are the lowest in the brass, and can be widely used for ship parts, steam pipes, water pipe fittings and the like.

Dezincification corrosion is one of the main failure modes of brass, and the higher the Zn content, the more severe the dezincification corrosion. The zinc equivalent coefficient of Si is 10, so that the beta phase boundary line of a Cu-Zn phase diagram is greatly shifted to the left, and a small amount of Si can be added to form the biphase brass, thereby obviously improving the strength and the hardness of the alloy and simultaneously reducing the dezincification corrosion resistance of the silicon brass. In order to balance the performance contradiction, the existing lead-free silicon brass in domestic and foreign markets generally has the component characteristics of high silicon content and high copper content, wherein the mass percent of Si is about 2-3%, and the mass percent of Cu is mostly over 75%, such as HSi 80-3. The silicon brass has high cost, obviously poorer cutting performance than lead brass and low processing efficiency. According to the patent CN 104651660A, AS-cast silicon brass material with low copper and low silicon is used by domestic bathroom manufacturers, the AS-cast silicon brass material mainly comprises the following raw materials, by mass, Cu 60-63 and Si 0.5-0.9, but the Pb content of the AS-cast silicon brass material is still higher than 0.1%, the dezincification layer depth is 152.86-174.62 μm, and although the dezincification layer depth is smaller than that of HPb59-1 tested under the same condition (297.83 μm), the AS 2345-2006 requirement (less than or equal to 100 μm) can not be met.

The invention aims at the kitchen industry, and improves the dezincification corrosion resistance of the low-silicon brass by adding trace arsenic elements, thinning matrix tissues and other methods based on the design idea of the components of the low-silicon low-copper lead-free silicon brass.

Disclosure of Invention

Aiming at the problems, the invention provides a preparation method of the dezincification-resistant lead-free low-silicon extruded arsenic brass rod with good dezincification corrosion resistance, high strength and good processing performance.

In order to solve the technical problem, the invention adopts the following scheme: a preparation method of an anti-dezincification lead-free low-silicon extrusion arsenic brass rod comprises the steps of smelting the following raw materials, by mass, Cu 62-65%, Si 0.6-1.0%, As0.07-0.12%, Al 0.5-0.8%, Fe 0.03-0.1%, Pb < 0.1%, the balance of Zn and impurities with the total amount not greater than 0.35%, then obtaining a solid brass rod through an introduction casting and extrusion process, wherein the step of introducing casting and extruding and compacting a core brass rod comprises the following steps:

1) firstly adding 200-300 kg of pure red copper rice in a cored power frequency furnace, wherein the adding amount of the pure red copper rice is 10-15% of the total raw materials, when the pure red copper rice is in a semi-molten state, filling industrial pure silicon with the granularity of less than 1cm accounting for 0.6-1.0% of the total raw materials into a copper pipe with a proper diameter, horizontally pressing the copper pipe into copper liquid, immediately paving 150-200 kg of the pure red copper rice on the surface of the copper liquid, wherein the adding amount of the pure red copper rice is 7.5-10% of the total raw materials, uniformly scattering 1 kg of a smelting slag removal agent, and preserving heat at 950-980 ℃ for 20min to ensure that the silicon is fully alloyed with the red copper rice under the condition of oxygen isolation; after the heat preservation is finished, respectively pressing preheated aluminum ingots, copper-iron intermediate alloys and copper-arsenic intermediate alloys which account for 0.5-0.8% of the total raw materials, wherein the addition amount of the copper-iron intermediate alloys ensures that the Fe content in the total raw materials reaches 0.03-0.1%, the addition amount of the copper-arsenic intermediate alloys ensures that the As content in the total raw materials reaches 0.07-0.12%, fully stirring and standing for 10 min;

2) adding a red copper plate, wherein the addition amount is to ensure that the Cu content in the total raw materials reaches 62-65%, the red copper plate is standard cathode copper, pressing in a preheated 0# zinc ingot accounting for 32.53-36.8% of the total raw materials when the melting amount of the copper plate reaches 70-80%, fully and uniformly stirring after melting, uniformly scattering 1.5kg of environment-friendly slag removal flux on the surface of the copper liquid, and standing for 10-15 min at 1020 ℃;

3) sampling and detecting components, and adjusting the components according to component detection data;

4) flaming, stirring, ash removing and slag removing, wherein in the ash removing process, a copper ash spoon is required to stay at a furnace mouth for about 20s when removing ash from copper water so as to ensure that the copper water in the ash completely flows into a crucible;

5) pressing weighed refiner into copper liquid by using a bell jar, fully stirring, and standing for 15-20 min at 1020 ℃, wherein the refiner is a combination of K salt or sodium salt taking F, Si, O, Mn and Ti as one or more negative valence acid radical ions, and the relation between the addition amount and the total raw materials is 75-125 g/T;

6) carrying out tests on fluidity, crystallization state, number and distribution of impurity points of cast ingots in a polished state and the like, if the roughness of the inner surface of the light cup, the number of impurity points of the polished surface and the crystal structure form meet the requirements, casting, otherwise, continuously carrying out refining treatment until the refining requirement is met, and obtaining copper liquid with Pb less than 0.1%;

7) pouring copper liquid which meets the refining requirement and contains less than 0.1% of Pb into a heat preservation furnace, installing a crystallizer on a copper water outlet of the heat preservation furnace, and correcting the center by using a traction rod during installation so as to ensure that the copper liquid is coaxial with a tractor;

8) the method comprises the steps of raising the temperature of copper water in a heat preservation furnace to a small flame spraying state, enabling the industrial voltage to be 250-300V, simultaneously feeding a small amount of cooling water into a water cooling jacket, enabling the water amount to be 2.5L/s, starting to use a tractor for casting after preparation work is done, slowing the speed of the tractor to 40-60 mm/min when casting begins, reducing the voltage to 180-240V after casting is finished, regulating the speed of the tractor to 60-80 mm/min, turning on a cooling water switch, enabling the water amount to be 5.0L/s, regulating the speed of the tractor to 80-100 mm/min when the length of a cast copper ingot reaches more than one meter, meeting technological requirements, synchronously sawing the tractor to the length needing sawing after the cast copper ingot is normal, and sawing the long cast copper ingot into the short cast copper ingot suitable for extrusion;

the step of extruding the copper bar by the casting copper ingot is to preheat the short casting copper ingot and then place the short casting copper ingot in an extrusion cylinder of an extrusion device, and force is applied to one end of the short casting copper ingot through an extrusion shaft, so that the copper ingot material flows out from a die hole of an extrusion die, and the brass bar with the required section shape and size is obtained.

The further improvement is that: the extrusion device comprises an extrusion cylinder, an extrusion die and an extrusion shaft, wherein the extrusion cylinder is internally provided with an extrusion hole capable of accommodating an extruded product, the extrusion shaft is arranged at one end of the extrusion hole, the extrusion die is fixedly arranged at one end of the extrusion cylinder, which is far away from the extrusion shaft, the extrusion die is provided with an extrusion die hole capable of extruding the extruded product, and the free end of the extrusion shaft is linked with a pushing and pressing driving device and can simultaneously advance or retreat through the pushing and pressing driving device.

The further improvement is that: and an extrusion gasket is arranged at the front end of the extrusion shaft in the extrusion hole of the extrusion cylinder.

The further improvement is that: the temperature of the flaming in the step 4) is 1050-1150 ℃.

By adopting the technical scheme, the invention has the beneficial effects that: the invention adopts the specific component proportion and the specific preparation method to prepare the solid brass rod, strictly controls the adding sequence of the raw materials in the production process, avoids the burning loss of the effective components of the raw materials, and selects the most appropriate adding methodThe additive amount is added to obtain an accumulation effect, so that the dezincification corrosion resistance of the lead-free brass rod is improved under the condition of lead-free components which reach the lead brass processing performance. The Cu content in the components is not higher than 65%, the Si content is 0.6-1.0%, the strength and the hardness of the brass alloy are improved, the requirements of low copper and low silicon components are met, and the cost is effectively reduced; as in the components increases overpotential of copper precipitation reaction, so that CuCl is easily generated on the surface of brass₂The film, which is a continuous, uniform protective film, can exist stably, thus retarding dezincification corrosion reaction. The Pb content in the components is only from impurity elements of the raw materials; al in the components not only improves the melt fluidity, but also is beneficial to an oxide film on the surface of the alloy and plays a role in passivation and corrosion prevention; the Fe content is controlled to be 0.03-0.1%, which is beneficial to grain refinement and reduces macro columnar crystal regions.

In the manufacturing method, pure red copper rice is used as a crucible bottom pre-melting material, so that the melting time can be saved, the copper liquid is controlled to be in a semi-molten state, the viscosity of the copper liquid is increased, the floating of low-density raw materials is inhibited, and the element absorption rate is improved; pressing raw materials with low melting point, low density or small amount into the low-temperature copper liquid and ensuring sufficient standing time, can effectively prevent oxidation burning loss, is beneficial to full diffusion reaction of elements, is convenient for controlling components and saves production cost; the high-temperature high-viscosity characteristic of the Cu-Zn binary alloy in a semi-solid phase area is utilized, and pure silicon replaces the copper-silicon intermediate alloy, so that the production cost is reduced; the slag removing agent is added in proper smelting stage in multiple times, so that the slag removing agent can be ensured to fully adsorb the oxidized slag inclusion in the copper liquid, the failure of the slag removing agent is avoided, the copper liquid is comprehensively purified by further combining with flame spraying treatment, the distribution uniformity of effective components can be improved, the probability of forming a primary battery by slag inclusion and a base body is reduced, and the corrosion speed is reduced; from the angles of similar crystal structure and equivalent lattice constant, a proper amount of Fe element is added, which is beneficial to heterogeneous nucleation, strengthens the grain refinement effect, increases the grain boundary area, reduces the area of the copper-zinc alloy anode and prevents selective preferential dissolution of zinc; the proportion of macroscopic isometric crystals in the cast ingot is increased, and adverse structure factors influencing the compactness of the cast ingot are reduced.

Drawings

FIG. 1 is a schematic representation of the macro-microstructure of dezincification resistant lead-free silicon arsenic brass;

FIG. 2 is a schematic representation of the microstructure of dezincification resistant lead-free silicon arsenic brass;

FIG. 3 is a schematic structural view of an extrusion apparatus according to an embodiment of the present invention.

Detailed Description

The invention will now be further described with reference to the accompanying drawings and specific embodiments.

The first embodiment is as follows: the anti-dezincification lead-free low-silicon extruded arsenic brass rod comprises the following raw materials, by mass, Cu 62%, Si 0.6%, As0.07%, Al 0.5%, Fe 0.03%, Pb0.06%, Zn36.7% and impurities accounting for 0.04%.

The preparation method of the anti-dezincification lead-free low-silicon extrusion arsenic brass rod comprises the following steps:

1) firstly adding 200kg of pure red copper rice in a cored power frequency furnace, wherein the adding amount of the pure red copper rice is 10% of the total raw materials, when the furnace is in a semi-molten state, filling industrial pure silicon with the granularity of less than 1cm accounting for 0.6% of the total raw materials into a copper pipe with a proper diameter, horizontally pressing the copper pipe into copper liquid, immediately paving 150g of the pure red copper rice on the surface of the copper liquid, wherein the adding amount of the pure red copper rice is 7.5% of the total raw materials, uniformly scattering 1 kg of a smelting slag remover, and preserving heat at 950-980 ℃ for 20min to ensure that the silicon is fully alloyed with the pure red copper rice under the condition of oxygen isolation; after heat preservation is finished, respectively pressing preheated aluminum ingots, copper-iron intermediate alloys and copper-arsenic intermediate alloys which account for 0.5% of the total raw materials, wherein the addition amount of the copper-iron intermediate alloys ensures that the Fe content in the total raw materials reaches 0.03%, the addition amount of the copper-arsenic intermediate alloys ensures that the As content in the total raw materials reaches 0.07%, and fully stirring and standing for 10 min;

2) adding a red copper plate, wherein the addition amount is to ensure that the Cu content in the total raw materials reaches 62%, the red copper plate is standard cathode copper, pressing in a preheated 0# zinc ingot accounting for 36.7% of the total raw materials when the melting amount of the copper plate reaches 70-80%, fully and uniformly stirring after melting, uniformly scattering 1.5kg of environment-friendly slag removal flux on the surface of the copper liquid, and standing for 10-15 min at 1020 ℃;

3) sampling and detecting components, and adjusting the components according to component detection data;

4) flaming, stirring, ash beating and slag fishing, wherein in the ash beating process, a copper ash spoon is required to stay at a furnace mouth for about 20s when beating ash away from copper water so as to ensure that the copper water in the ash completely flows into a crucible, and the flaming temperature is 1050-1150 ℃;

5) pressing weighed refiner into copper liquid by using a bell jar, fully stirring, and standing for 15-20 min at 1020 ℃, wherein the refiner is a combination of K salt or sodium salt taking F, Si, O, Mn and Ti as one or more negative valence acid radical ions, and the relation between the addition amount of the refiner and the total raw materials is 75-125 g/T;

6) carrying out tests on fluidity, a crystallization state, the number and distribution of impurity points of cast ingots in a polishing state and the like, if the roughness of the inner surface of the light cup, the number of impurity points of the polished surface and the crystal structure form meet the requirements, casting, otherwise, continuously carrying out refining treatment until the refining requirement is met, and obtaining copper liquid with 0.06% of Pb;

7) pouring copper liquid which meets the refining requirement and contains 0.06% of Pb into a heat preservation furnace, installing a crystallizer on a copper water outlet of the heat preservation furnace, and correcting the center by using a traction rod during installation so as to ensure that the copper liquid is coaxial with a tractor;

8) the method comprises the steps of raising the temperature of copper water in a heat preservation furnace to a small flame spraying state, enabling the industrial voltage to be 250-300V, simultaneously feeding a small amount of cooling water into a water cooling jacket, enabling the water amount to be 2.5L/s, starting to use a tractor for casting after preparation work is done, slowing the speed of the tractor to 40-60 mm/min when casting begins, reducing the voltage to 180-240V after casting is finished, regulating the speed of the tractor to 60-80 mm/min, turning on a cooling water switch, enabling the water amount to be 5.0L/s, regulating the speed of the tractor to 80-100 mm/min when the length of a cast copper ingot reaches more than one meter, meeting technological requirements, synchronously sawing the tractor to the length needing sawing after the cast copper ingot is normal, and sawing the long cast copper ingot into the short cast copper ingot suitable for extrusion;

the step of extruding the copper bar by the casting copper ingot is to preheat the short casting copper ingot and then place the short casting copper ingot in an extrusion cylinder of an extrusion device, and force is applied to one end of the short casting copper ingot through an extrusion shaft, so that the copper ingot material flows out from a die hole of an extrusion die, and the brass bar with the required section shape and size is obtained.

As shown in fig. 3, the extrusion device includes an extrusion cylinder 1, an extrusion die 2 and an extrusion shaft 3, the extrusion cylinder 1 has an extrusion hole 11 capable of accommodating an extruded product, the extrusion shaft 3 is disposed at one end of the extrusion hole 11, the extrusion die 2 is fixedly disposed at an end of the extrusion cylinder 1 away from the extrusion shaft 3, the extrusion die 2 is provided with an extrusion die hole 21 capable of extruding the extruded product, an extrusion pad 4 is further disposed at a front end of the extrusion shaft in the extrusion hole of the extrusion cylinder 1, and a free end of the extrusion shaft is linked with a pushing drive device and can simultaneously advance or retreat through the pushing drive device. It is to be noted that the extruded copper ingot needs to be heated to 720 ℃ to 760 ℃.

As shown in fig. 1 and fig. 2, the macroscopic isometric crystal area of the cross section of the ingot is close to 100%, the macroscopic grains of the subsurface layer are slightly coarse, the average size of the macroscopic grains is about 50 μm, and the average size of the macroscopic grains of other areas is less than 40 μm; the brass structure is a two-phase brass structure, has more beta phases and obvious edge passivation effect, is elliptical or oval, and is beneficial to avoiding stress concentration when stressed; the hardness of the dezincification-resistant lead-free low-silicon arsenic brass is about 96HRB, which is higher than that of cast HPb59-1 (about 80-82 HRB), and the average dezincification layer depth is about 76 mu m.

Example two:

the anti-dezincification lead-free low-silicon extruded arsenic brass rod comprises the following raw materials, by mass, 65% of Cu, 1.0% of Si, 0.12% of As0.8% of Al, 0.1% of Fe, 0.09% of PbB, 32.79% of ZnB and 0.1% of impurities in total.

The preparation method of the dezincification-resistant lead-free low-silicon extruded arsenic brass rod comprises the following steps:

1) adding 300kg of pure red copper rice into a cored power frequency furnace, wherein the adding amount of the pure red copper rice is 15% of the total raw materials, when the pure red copper rice is in a semi-molten state, filling industrial pure silicon with the granularity of less than 1cm accounting for 1.0% of the total raw materials into a copper pipe with a proper diameter, horizontally pressing the industrial pure silicon into copper liquid, immediately paving 200 g of the pure red copper rice on the surface of the copper liquid, wherein the adding amount of the pure red copper rice is 10% of the total raw materials, uniformly scattering 1 kg of smelting slag removing agent, and preserving heat at 950-980 ℃ for 20min to ensure that the silicon is fully alloyed with the pure red copper rice under the condition of oxygen isolation; after heat preservation is finished, respectively pressing preheated aluminum ingot, copper-iron intermediate alloy and copper-arsenic intermediate alloy which account for 0.8% of the total raw materials, wherein the addition amount of the copper-iron intermediate alloy ensures that the Fe content in the total raw materials reaches 0.1%, the addition amount of the copper-arsenic intermediate alloy ensures that the As content in the total raw materials reaches 0.12%, fully stirring and standing for 10 min;

2) adding a red copper plate, wherein the addition amount ensures that the Cu content in the total raw materials reaches 65%, the red copper plate is standard cathode copper, pressing in a preheated 0# zinc ingot accounting for 32.79% of the total raw materials when the melting amount of the copper plate reaches 70-80%, fully and uniformly stirring after melting, uniformly scattering 1.5kg of environment-friendly slag removal flux on the surface of the copper liquid, and standing for 10-15 min at 1020 ℃;

3) sampling and detecting components, and adjusting the components according to component detection data;

4) flaming, stirring, ash beating and slag fishing, wherein in the ash beating process, a copper ash spoon is required to stay at a furnace mouth for about 20s when beating ash away from copper water so as to ensure that the copper water in the ash completely flows into a crucible, and the flaming temperature is 1050-1150 ℃;

5) pressing weighed refiner into copper liquid by using a bell jar, fully stirring, and standing for 15-20 min at 1020 ℃, wherein the refiner is a combination of K salt or sodium salt taking F, Si, O, Mn and Ti as one or more negative valence acid radical ions, and the relation between the addition amount of the refiner and the total raw materials is 75-125 g/T;

6) carrying out tests on fluidity, a crystalline state, the number and distribution of impurity points of cast ingots in a polished state and the like, if the roughness of the inner surface of the light cup, the number of impurity points of the polished surface and the crystalline structure form meet the requirements, casting, otherwise, continuously carrying out refining treatment until the refining requirement is met, and obtaining copper liquid with the Pb of 0.09%;

7) pouring copper liquid which meets the refining requirement and contains 0.09% of Pb into a heat preservation furnace, installing a crystallizer on a copper water outlet of the heat preservation furnace, and correcting the center by using a traction rod during installation so as to ensure that the copper liquid is coaxial with a tractor;

8) the method comprises the steps of raising the temperature of copper water in a heat preservation furnace to a small flame spraying state, enabling the industrial voltage to be 250-300V, simultaneously feeding a small amount of cooling water into a water cooling jacket, enabling the water amount to be 2.5L/s, starting to use a tractor for casting after preparation work is done, slowing the speed of the tractor to 40-60 mm/min when casting begins, reducing the voltage to 180-240V after casting is finished, regulating the speed of the tractor to 60-80 mm/min, turning on a cooling water switch, enabling the water amount to be 5.0L/s, regulating the speed of the tractor to 80-100 mm/min when the length of a cast copper ingot reaches more than one meter, meeting technological requirements, synchronously sawing the tractor to the length needing sawing after the cast copper ingot is normal, and sawing the long cast copper ingot into the short cast copper ingot suitable for extrusion;

the step of extruding the copper bar by the casting copper ingot is to preheat the short casting copper ingot and then place the short casting copper ingot in an extrusion cylinder of an extrusion device, and force is applied to one end of the short casting copper ingot through an extrusion shaft, so that the copper ingot material flows out from a die hole of an extrusion die, and the brass bar with the required section shape and size is obtained.

Example three:

an anti-dezincification lead-free low-silicon extrusion arsenic brass rod comprises the following raw materials, by mass, 63% of Cu, 0.8% of Si, 0.10% of As0.6% of Al, 0.05% of Fe, 0.04% of Pb0.3% of Zn and 0.11% of impurities in total.

The preparation method of the dezincification-resistant lead-free low-silicon extruded arsenic brass rod comprises the following steps:

1) adding 300kg of pure red copper rice into a cored power frequency furnace, wherein the adding amount of the pure red copper rice is 15% of the total raw materials, when the pure red copper rice is in a semi-molten state, filling industrial pure silicon with the granularity of less than 1cm accounting for 0.8% of the total raw materials into a copper pipe with a proper diameter, horizontally pressing the industrial pure silicon into copper liquid, immediately paving 200 g of the pure red copper rice on the surface of the copper liquid, wherein the adding amount of the pure red copper rice is 10% of the total raw materials, uniformly scattering 1 kg of smelting slag removing agent, and preserving heat at 950-980 ℃ for 20min to ensure that the silicon is fully alloyed with the pure red copper rice under the condition of oxygen isolation; after heat preservation is finished, respectively pressing preheated aluminum ingot, copper-iron intermediate alloy and copper-arsenic intermediate alloy which account for 0.6% of the total raw materials, wherein the addition amount of the copper-iron intermediate alloy ensures that the Fe content in the total raw materials reaches 0.05%, the addition amount of the copper-arsenic intermediate alloy ensures that the As content in the total raw materials reaches 0.10%, and fully stirring and standing for 10 min;

2) adding a red copper plate, wherein the addition amount is to ensure that the Cu content in the total raw materials reaches 63%, the red copper plate is standard cathode copper, pressing in a preheated 0# zinc ingot accounting for 35.3% of the total raw materials when the melting amount of the copper plate reaches 70-80%, fully and uniformly stirring after melting, uniformly scattering 1.5kg of environment-friendly slag removal flux on the surface of the copper liquid, and standing for 10-15 min at 1020 ℃;

3) sampling and detecting components, and adjusting the components according to component detection data;

4) flaming, stirring, ash beating and slag fishing, wherein in the ash beating process, a copper ash spoon is required to stay at a furnace mouth for about 20s when beating ash away from copper water so as to ensure that the copper water in the ash completely flows into a crucible, and the flaming temperature is 1050-1150 ℃;

5) pressing weighed refiner into copper liquid by using a bell jar, fully stirring, and standing for 15-20 min at 1020 ℃, wherein the refiner is a combination of K salt or sodium salt taking F, Si, O, Mn and Ti as one or more negative valence acid radical ions, and the relation between the addition amount of the refiner and the total raw materials is 75-125 g/T;

6) carrying out tests on fluidity, crystalline state, number and distribution of impurity points of cast ingots in a polished state and the like, if the roughness of the inner surface of the light cup, the number of impurity points of the polished surface and the crystalline structure form meet the requirements, casting, otherwise, continuously carrying out refining treatment until the refining requirement is met, and obtaining copper liquid with 0.04 percent of Pb;

7) pouring copper liquid which meets the refining requirement and contains 0.04% of Pb into a heat preservation furnace, installing a crystallizer on a copper water outlet of the heat preservation furnace, and correcting the center by using a traction rod during installation so as to ensure that the copper liquid is coaxial with a tractor;

8) the method comprises the steps of raising the temperature of copper water in a heat preservation furnace to a small flame spraying state, enabling the industrial voltage to be 250-300V, simultaneously feeding a small amount of cooling water into a water cooling jacket, enabling the water amount to be 2.5L/s, starting to use a tractor for casting after preparation work is done, slowing the speed of the tractor to 40-60 mm/min when casting begins, reducing the voltage to 180-240V after casting is finished, regulating the speed of the tractor to 60-80 mm/min, turning on a cooling water switch, enabling the water amount to be 5.0L/s, regulating the speed of the tractor to 80-100 mm/min when the length of a cast copper ingot reaches more than one meter, meeting technological requirements, synchronously sawing the tractor to the length needing sawing after the cast copper ingot is normal, and sawing the long cast copper ingot into the short cast copper ingot suitable for extrusion;

the step of extruding the copper bar by the casting copper ingot is to preheat the short casting copper ingot and then place the short casting copper ingot in an extrusion cylinder of an extrusion device, and force is applied to one end of the short casting copper ingot through an extrusion shaft, so that the copper ingot material flows out from a die hole of an extrusion die, and the brass bar with the required section shape and size is obtained.

Based on the technical scheme: the cost of the preparation method of the dezincification-resistant lead-free low-silicon extruded arsenic brass rod can achieve the purpose of the invention within the following weight component proportion range: cu 62-65%, Si 0.6-1.0%, As0.07-0.12%, Al 0.5-0.8%, Fe0.03-0.1%, Pb < 0.1%, and the balance of Zn and impurities with the total amount not more than 0.35%.

The solid brass rod is prepared by adopting a specific component ratio and a specific preparation method, the adding sequence of each raw material is strictly controlled in the production process, the burning loss of the effective components of each raw material is avoided, the accumulation effect is obtained by selecting the most appropriate adding amount, and the dezincification corrosion resistance of the lead-free brass rod is improved under the condition of lead-free components and lead brass processability. The Cu content in the components is not higher than 65%, the Si content is 0.6-1.0%, the strength and the hardness of the brass alloy are improved, the requirements of low copper and low silicon components are met, and the cost is effectively reduced; as in the components increases overpotential of copper precipitation reaction, so that CuCl is easily generated on the surface of brass₂The film, which is a continuous, uniform protective film, can exist stably, thus retarding dezincification corrosion reaction. The Pb content in the components is only from impurity elements of the raw materials; al in the components not only improves the melt fluidity, but also is beneficial to an oxide film on the surface of the alloy and plays a role in passivation and corrosion prevention; the Fe content is controlled to be 0.03-0.1%, which is beneficial to grain refinement and reduces macro columnar crystalsAnd (4) a zone.

In the manufacturing method, pure red copper rice is used as a crucible bottom pre-melting material, so that the melting time can be saved, the copper liquid is controlled to be in a semi-molten state, the viscosity of the copper liquid is increased, the floating of low-density raw materials is inhibited, and the element absorption rate is improved; pressing raw materials with low melting point, low density or small amount into the low-temperature copper liquid and ensuring sufficient standing time, can effectively prevent oxidation burning loss, is beneficial to full diffusion reaction of elements, is convenient for controlling components and saves production cost; the high-temperature high-viscosity characteristic of the Cu-Zn binary alloy in a semi-solid phase area is utilized, and pure silicon replaces the copper-silicon intermediate alloy, so that the production cost is reduced; the slag removing agent is added in proper smelting stage in multiple times, so that the slag removing agent can be ensured to fully adsorb the oxidized slag inclusion in the copper liquid, the failure of the slag removing agent is avoided, the copper liquid is comprehensively purified by further combining with flame spraying treatment, the distribution uniformity of effective components can be improved, the probability of forming a primary battery by slag inclusion and a base body is reduced, and the corrosion speed is reduced; from the angles of similar crystal structure and equivalent lattice constant, a proper amount of Fe element is added, which is beneficial to heterogeneous nucleation, strengthens the grain refinement effect, increases the grain boundary area, reduces the area of the copper-zinc alloy anode and prevents selective preferential dissolution of zinc; the proportion of macroscopic isometric crystals in the cast ingot is increased, and adverse structure factors influencing the compactness of the cast ingot are reduced.

The above description is only an embodiment utilizing the technical content of the present disclosure, and any modification and variation made by those skilled in the art can be covered by the claims of the present disclosure, and not limited to the embodiments disclosed.

Claims (4)

1. The preparation method of the dezincification-resistant lead-free low-silicon extruded arsenic brass rod is characterized by comprising the following steps of: the method comprises the following steps of smelting the following raw materials, by mass, Cu 62-65%, Si 0.6-1.0%, As0.07-0.12%, Al 0.5-0.8%, Fe 0.03-0.1%, Pb < 0.1%, and the balance of Zn and impurities with the total amount not more than 0.35%, and then obtaining a solid brass rod through an introduction casting and extrusion process, wherein the step of introducing casting and extruding and compacting the core brass rod comprises the following steps:

1) firstly adding 200-300 kg of pure red copper rice in a cored power frequency furnace, wherein the adding amount of the pure red copper rice is 10-15% of the total raw materials, when the pure red copper rice is in a semi-molten state, filling industrial pure silicon with the granularity of less than 1cm accounting for 0.6-1.0% of the total raw materials into a copper pipe with a proper diameter, horizontally pressing the copper pipe into copper liquid, immediately paving 150-200 kg of the pure red copper rice on the surface of the copper liquid, wherein the adding amount of the pure red copper rice is 7.5-10% of the total raw materials, uniformly scattering 1 kg of a smelting slag removal agent, and preserving heat at 950-980 ℃ for 20min to ensure that the silicon is fully alloyed with the red copper rice under the condition of oxygen isolation; after heat preservation is finished, respectively pressing preheated aluminum ingots, copper-iron intermediate alloys and copper-arsenic intermediate alloys which account for 0.5-0.8% of the total raw materials, wherein the addition amount of the copper-iron intermediate alloys ensures that the Fe content in the total raw materials reaches 0.03-0.1%, the addition amount of the copper-arsenic intermediate alloys ensures that the As content in the total raw materials reaches 0.07-0.12%, and fully stirring and standing for 10 min;

2) adding a red copper plate, wherein the addition amount is to ensure that the Cu content in the total raw materials reaches 62-65%, the red copper plate is standard cathode copper, pressing in a preheated 0# zinc ingot accounting for 32.53-36.8% of the total raw materials when the melting amount of the copper plate reaches 70-80%, fully and uniformly stirring after melting, uniformly scattering 1.5kg of environment-friendly slag removal flux on the surface of the copper liquid, and standing for 10-15 min at 1020 ℃;

3) sampling and detecting components, and adjusting the components according to component detection data;

4) flaming, stirring, ash removing and slag removing, wherein in the ash removing process, a copper ash spoon is required to stay at a furnace mouth for 20s when removing ash from copper water so as to ensure that the copper water in the ash completely flows into a crucible;

5) pressing weighed refiner into copper liquid by using a bell jar, fully stirring, and standing for 15-20 min at 1020 ℃, wherein the refiner is a combination of K salt or sodium salt taking F, Si, O, Mn and Ti as one or more negative valence acid radical ions, and the relation between the addition amount and the total raw materials is 75-125 g/T;

6) carrying out fluidity, crystalline state and polished state ingot casting impurity point quantity and distribution inspection, if the roughness of the inner surface of the light cup, the impurity point number of the polished surface and the crystalline structure form meet the requirements, casting, otherwise, continuing refining treatment until the refining requirement is met, and obtaining copper liquid with Pb less than 0.1%;

7) pouring copper liquid which meets the refining requirement and contains less than 0.1% of Pb into a heat preservation furnace, installing a crystallizer on a copper water outlet of the heat preservation furnace, and correcting the center by using a traction rod during installation so as to ensure that the copper liquid is coaxial with a tractor;

8) the method comprises the steps of raising the temperature of copper water in a heat preservation furnace to a small flame spraying state, enabling the industrial voltage to be 250-300V, simultaneously feeding a small amount of cooling water into a water cooling jacket, enabling the water amount to be 2.5L/s, starting to use a tractor for casting after preparation work is done, slowing the speed of the tractor to 40-60 mm/min when casting begins, reducing the voltage to 180-240V after casting is finished, regulating the speed of the tractor to 60-80 mm/min, turning on a cooling water switch, enabling the water amount to be 5.0L/s, regulating the speed of the tractor to 80-100 mm/min when the length of a cast copper ingot reaches more than one meter, meeting technological requirements, synchronously sawing the tractor to the length needing sawing after the cast copper ingot is normal, and sawing the long cast copper ingot into the short cast copper ingot suitable for extrusion;

the step of extruding the copper bar by the casting copper ingot is to preheat the short casting copper ingot and then place the short casting copper ingot in an extrusion cylinder of an extrusion device, and force is applied to one end of the short casting copper ingot through an extrusion shaft, so that the copper ingot material flows out from a die hole of an extrusion die, and the brass bar with the required section shape and size is obtained.

2. The method for preparing the dezincification-resistant lead-free low-silicon extruded arsenic brass rod as claimed in claim 1, wherein: the extrusion device comprises an extrusion cylinder, an extrusion die and an extrusion shaft, wherein the extrusion cylinder is internally provided with an extrusion hole capable of accommodating an extruded product, the extrusion shaft is arranged at one end of the extrusion hole, the extrusion die is fixedly arranged at one end of the extrusion cylinder, which is far away from the extrusion shaft, the extrusion die is provided with an extrusion die hole capable of extruding the extruded product, and the free end of the extrusion shaft is linked with a pushing and pressing driving device and can simultaneously advance or retreat through the pushing and pressing driving device.

3. The method for preparing the dezincification-resistant lead-free low-silicon extruded arsenic brass rod as claimed in claim 2, wherein: and an extrusion gasket is arranged at the front end of the extrusion shaft in the extrusion hole of the extrusion cylinder.

4. The method for preparing the dezincification-resistant lead-free low-silicon extruded arsenic brass rod as claimed in claim 1, wherein: the temperature of the flaming in the step 4) is 1050-1150 ℃.

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