WO2018039817A1

WO2018039817A1 - Electroslag fusion preparation method for large-sized curved blade slab

Info

Publication number: WO2018039817A1
Application number: PCT/CN2016/000587
Authority: WO
Inventors: 娄延春; 熊云龙; 陈瑞; 宋照伟; 王安国; 王云霞
Original assignee: 沈阳铸造研究所
Priority date: 2016-08-31
Filing date: 2016-10-27
Publication date: 2018-03-08
Also published as: US20190022746A1; CN107774962B; CN107774962A

Abstract

An electroslag fusion preparation method for a large-sized curved blade slab. First, for a part having a high mold filling difficulty, prefabricated curved slabs (5, 6) are prepared according to the shape and the size of a curved blade slab and by using an electroslag casting technology, and the prefabricated curved slabs are placed on a side edge of a crystallizer (2); and then, liquid-state metal molten by a consumable electrode (3) and one or two electroslag prefabricated slabs placed in the crystallizer are fused together by using an electroslag fusion process, so as to form a large-sized curved blade slab cast. The interior and the surface of the large-sized curved blade slab cast prepared by using the method have good quality, accordingly the material utilization rate can be improved, the processing period can be shortened, and especially the large-sized curved blade slab cast has high anti-fatigue performance, high crack-resistant performance and high extension performance. The method is more suitable for producing a large-sized curved blade slab cast having a great width-to-thickness ratio and having an uneven thickness, for example, a large-sized or super-sized curved blade slab cast having a width-to-thickness ratio of higher than 10 and a unit weight of more than 10 tons.

Description

Electroslag fusion manufacturing method for large curved blade slab

Technical field

The invention relates to a manufacturing process of a large aspect ratio curved casting, and particularly provides a method for manufacturing an electroslag fusion of a large curved blade slab.

Background technique

In the field of equipment manufacturing, various irregular wide and thick plate castings and forgings are often used, which are characterized by large width to thickness ratio and irregular sectional shape. As one of the important basic components of high-end equipment, the quality requirements of such shaped plate castings are extremely strict. For example, the quality problems of turbine generator blade castings almost limit the overall operating life of the turbine unit.

At present, the methods for producing such castings and forgings at home and abroad mainly include three methods of ordinary sand casting, forging and electroslag casting.

(1) Due to the limitations of the process itself, ordinary sand casting products are often difficult to meet the requirements for use due to poor internal quality; (2) The internal quality of wide and thick plate castings and forgings produced by forging slabs is good, but the metal utilization rate is good. Very low, the production cost and construction period have increased greatly, and it violates the green manufacturing concept; (3) Electroslag casting can directly produce wide and thick plate castings and forgings that meet the requirements according to the contour of the product. The solidification quality and mechanical properties are excellent, and the same material can be achieved. Forging material standard. At present, the inventors have produced an integral blade compact by electroslag casting, and have obtained a patent for invention (a method for manufacturing electroslag casting of a turbine blade compact, publication number: CN 104174834A). However, this process is only effective for slab castings with a relatively small aspect ratio. For large slab castings with large aspect ratio (width to thickness ratio > 10) and complex cross-sectional shape, consumable electrode fabrication and mold cooling conditions are limited. The molten metal produced by electroslag casting cannot overflow to the farthest area of the thin side, which causes the forming quality of the thin side of the casting to be poor, which limits the further application of the method.

In addition to the above three methods for producing wide and thick plate castings and forgings, the Japanese patent (JP 1999019791A) and the Chinese patent (publication number: CN 102029378A) each propose a method of utilizing two original blanks. A new method of slag process fusion. However, these two methods are only suitable for the welding of equal-thickness steel plates or ingots, and it is difficult to apply to large-width-to-thickness castings having irregular shapes in cross section.

Summary of the invention

The invention provides a method for manufacturing electroslag fusion of a large curved blade slab, in particular, a large curved blade slab casting with large width-to-thickness ratio and large thickness difference, and the method mainly uses electroslag. The fusing process fuses the molten metal melted by the consumable electrode with one or two electroslag precast slabs placed in advance in the crystallizer to form a large curved panel blank casting.

The technical scheme of the present invention is as follows:

The invention relates to a method for manufacturing electroslag fusion of a large curved blade slab, which is characterized in that: according to the shape and sectional size of the curved blade slab, the blade slab is divided into 2-3 regions (see Figure 1-2), wherein: The prefabricated curved panel blank is prepared by electroslag casting technology in advance on the one-side or double-sided part with large thickness variation and filling difficulty, and placed in the side of the inner cavity of the crystallizer in advance; then the self-consumption electrode is fabricated by electroslag fusion process The molten metal liquid is fused with one or two electroslag precast slabs placed in the crystallizer to form a large curved blade slab casting.

The large curved blade slab casting prepared by the method of the invention has good internal and surface quality, can improve material utilization rate, shorten processing period and improve quality, especially high fatigue resistance and high resistance to crack generation. Expand performance. The process is more suitable for the production of large or super large curved blade slab castings with a width to thickness ratio of >10 and a single weight of more than 10 tons.

The specific electroslag fusion process steps are as follows:

(1), slag system and slag amount control: The main components of electroslag fusion slag system are mass percentage: CaF ₂ : 50-62%, Al ₂ O ₃ : 25-35%, CaO: 3 8%, trace components The amount added is not more than 5% of the total mass of the slag system; the multi-slag system is formed, wherein the trace component is one or more of MgO, SiO ₂ and TiO ₂ , and the thickness of the slag layer is equivalent diameter of the curved blade slab crystallizer 12 to 25%;

(2) Electroslag fusion process parameters: voltage: 70-120V, current density: 20000-60000A/m ² ;

(3), feeding process: using the intermittent feeding method for feeding, during the feeding period, firstly reduce the normal current to the minimum feeding current within 2 to 5 minutes, keep it for 1 to 2 minutes; The current reduced to a constant rate of 70 to 80% of the normal casting current in 3 minutes, so repeated 4 to 5 times, each time the highest current is 70 to 80% of the previous highest current, and the last time is reduced to zero.

The electroslag fusion manufacturing method of the large curved blade slab of the invention is characterized in that the single side precast slab can be fused or the double side precast slab can be fused by the electroslag casting process.

The electroslag fusion manufacturing method of the large curved blade slab of the invention is characterized in that: due to the relatively complicated precast curved panel blank, the consumable electrode selected for the electroslag casting precast slab is a sand casting electrode, and the electroslag fusion process is selected. The consumable electrode is a steel plate welding electrode. According to the size of the inner cavity of the blade slab mold, the self-consumption electrode filling ratio is 0.15-0.4.

The method for manufacturing electroslag fusion of the large curved blade slab of the present invention is characterized in that the large curved blade slab alloy material comprises: low carbon martensitic stainless steel 06Cr13Ni4Mo, 06Cr13Ni5Mo or 06Cr16Ni5Mo; ultra low carbon martensitic stainless steel 04Cr13Ni4Mo or 04Cr13Ni5Mo.

Compared with the prior art, the present invention has the following advantages:

(1) Electroslag casting is a special casting technology that integrates refining, solidification and solidification. By adjusting the slag ratio and optimizing the process, the inclusions in the consumable electrode can be further removed and the distribution pattern can be changed and reduced. The harmful elements such as P and S in the curved blade slab and the gas contents such as N, H and O improve the purity of the material.

(2) Electroslag fusion curved blade slab can meet the mechanical properties and flaw detection requirements of the same material forgings. It has uniform chemical composition, compact structure, no looseness, shrinkage hole and other defects. The inclusions are dispersed and have high fatigue resistance. Performance and high resistance to crack generation and expansion.

(3) The curved blade slab casting is solidified in the crystallizer, the cooling speed is fast, the crystallizer has high dimensional accuracy and small deformation, so the surface of the casting is smooth and the processing allowance is small, and the near net forming purpose is achieved.

(4) The electroslag fusion process effectively solves the problem of filling quality of large blade slabs, and the internal and surface quality of the prepared large curved blade slab castings is good. The process is more suitable for the production of large or super large curved blade slab castings with a width to thickness ratio of >10 and a single weight of more than 10 tons.

DRAWINGS

Figure 1 is a schematic view showing the structure of a single-sided fusion prefabricated slab.

Figure 2 is a schematic view showing the structure of a double-sided fusion prefabricated slab.

Fig. 3 is a schematic view showing a manufacturing method of electroslag fusion of a large curved blade slab.

Among them, 1, transformer, 2, combined water-cooled crystallizer, 3, electrode, 4, bottom water tank, 5, prefabricated slab I, 6, prefabricated slab II, 7, electroslag fusion zone, 8, metal melting pool, 9, liquid slag.

detailed description

Example 1:

Referring to FIG. 2 and FIG. 3, in the method for manufacturing electroslag fusion of a large curved blade slab according to the present invention, the selected blade slab material is martensitic stainless steel 06Cr13Ni4Mo, and the maximum width of the blade is about 4300 mm, the maximum height is 3400 mm, and the maximum thickness is obtained. It is 310mm and the minimum thickness is 65mm.

First, the precast slab I 5 and the precast slab II6 are respectively placed in the I zone and the III zone in the crystallizer, and then the transformer 1 is connected to the bottom water tank 4, the II zone and the electrode 3 through a wire to form a circuit, and the electrode 3 is in the liquid slag. 9 is melted by the resistance heat, and the liquid metal passes through the slag pool to form the molten metal pool 8. Under the action of the strong water-cooled crystallizer (the spiral groove of the inner wall of the crystallizer having a certain angle of elevation, increasing the cooling strength), The preformed slab I 5 and the preformed slab II 6 are fused together. Finally, Zone I, Zone II and Zone III together form the curved blade slab required for the experiment.

1 Combine the inner cavity size of the blank mold in the II zone, prepare the conformal steel plate electrode, and select the filling ratio to be 0.3; 2 The selected slag ratio is CaF ₂ : 60%, Al ₂ O ₃ : 32%, CaO: 6 %, MgO: 2% form a quaternary slag system, the thickness of the slag layer is 20% of the equivalent diameter of the curved blade slab mold; 3 power supply parameter selection: according to the casting size, the geometric parameters of the electrode and the crystallizer, and the melting process The casting voltage is 115V and the current density is 22000A/m ² ; during the 4-fold period, the normal current is firstly reduced to the minimum feeding current for 4 minutes within 4 minutes; then the minimum feeding current is uniformly increased within 2 minutes. Up to 70% of the normal casting current, repeated 4 times, each time the highest melting current is 70% of the previous highest casting current, the last time reduced to zero.

The large curved blade slab prepared by the invention meets the requirements of the drawings, and has good internal and surface quality. The mechanical properties of the compact after conventional heat treatment are R _P0.2 /650Mpa, R _m /845Mpa, A/26%, Z /62%, KV ₂ /101J.

Example 2:

In this experiment, the X-shaped curved blade slab of a power station is manufactured, and the martensitic stainless steel with material of 06Cr16Ni5Mo is selected. The prepared blade slab has a maximum width of 2600 mm, a maximum height of 2100 mm, a maximum thickness of 220 mm, and a minimum thickness of 30 mm.

First, a precast slab is placed on the side of the mold, the electrode is melted under the resistance heat of the liquid slag, and the liquid metal passes through the slag pool to form a molten metal pool. Under the action of the water-cooled crystallizer, the liquid metal liquid It is solidified and fused with pre-formed slabs placed in advance in the crystallizer to form a curved blade slab as required by the experiment.

1 combined with the remaining inner cavity size of the crystallizer, the preparation of the conformal steel plate electrode, the selected filling ratio is 0.26; 2 the selected slag ratio is CaF ₂ : 60%, Al ₂ O ₃ : 35%, CaO: 5% formation Three-dimensional slag system, the thickness of the slag layer is 21% of the equivalent diameter of the curved blade slab mold; 3 power supply parameter selection: according to the casting size, the geometric parameters of the electrode and the mold and the casting process, the casting voltage is determined to be 85V and the current density is 35000A / m ² ; 4 during the feeding period, firstly reduce the normal current to the minimum feeding current within 3 minutes to keep the minimum feeding current for 2 minutes; then increase the minimum feeding current to the normal casting current at a constant rate within 2 minutes. %, repeated 4 times, each time the highest melting current is 70% of the previous highest casting current, and the last time is reduced to zero.

The prepared large-scale curved blade slab is subjected to profile inspection, its dimensions meet the requirements of the drawings, and the surface has no slag groove defects; the mechanical properties of the compact after conventional heat treatment are R _P0.2 /634Mpa, R _m /810Mpa, A/25 %, Z/55%, KV ₂ /105J, meet the requirements for use.

The above embodiments are merely illustrative of the technical concept and the features of the present invention, and the purpose of the present invention is to enable those skilled in the art to understand the present invention and to implement the present invention, and the scope of the present invention is not limited thereto. Equivalent variations or modifications made in accordance with the spirit of the invention are intended to be included within the scope of the invention.

Claims

The invention relates to a method for manufacturing electroslag fusion of a large curved blade slab, which is characterized in that: according to the shape and sectional size of the curved blade slab, the blade slab is divided into 2-3 regions, wherein: the thickness variation of the section is large, and the filling is large. The difficult single-sided or double-sided part is prefabricated by electroslag casting technology to prepare the pre-formed curved panel blank, and placed in the side of the cavity of the crystallizer in advance; and then the molten metal melted by the consumable electrode is placed in the electroslag fusion process. One or two pieces of electroslag precast slabs in the crystallizer are fused together to form a large curved blade slab casting.
A method for manufacturing an electroslag fusion of a large curved blade slab according to claim 1, wherein the specific electroslag fusion process steps are as follows:

(1), slag system and slag amount control: The main components of electroslag fusion slag system are mass percentage: CaF 2 : 50-62%, Al 2 O 3 : 25-35%, CaO: 3 8%, trace components ≤ 5%; constitute a multi-slag system, wherein the trace component is one or more of MgO, SiO 2 , TiO 2 , and the thickness of the slag layer is 12 to 25% of the equivalent diameter of the curved blade slab crystallizer;

(2) Electroslag fusion process parameters: voltage: 70-120V, current density: 20000-60000A/m 2 ;

(3), feeding process: during the feeding period, firstly reduce the normal current to the minimum feeding current within 2 to 5 minutes, keep it for 1 to 2 minutes; then increase the minimum feeding current at a constant rate within 3 minutes. From 70 to 80% of the normal casting current, this is repeated 4 to 5 times, each time the highest current is 70 to 80% of the previous highest current, and the last time is reduced to zero.
The method of manufacturing an electroslag fusion of a large curved blade slab according to claim 1, wherein the curved blade is fused to one side of the precast slab or the double prefabricated slab.
The electroslag fusion manufacturing method for a large curved blade slab according to claim 1, wherein the electroslag-casting precast slab adopts a self-consumption electrode as a sand casting electrode, and the electroslag fusion process uses a steel plate tailored electrode; self-consumption electricity The pole filling ratio is 0.15 to 0.4.
The method for manufacturing an electroslag fusion of a large curved blade slab according to claim 1, wherein the large curved blade slab alloy material comprises: low carbon martensitic stainless steel 06Cr13Ni4Mo, 06Cr13Ni5Mo or 06Cr16Ni5Mo; ultra low carbon Markov Body stainless steel 04Cr13Ni4Mo or 04Cr13Ni5Mo.