LOW-LEAD BRASS ALLOY

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the priority benefit of Chinese patent application No. 201410247387.0, filed on Jun. 5, 2014. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of specification.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a low-lead brass alloy, and particularly to a low-lead free-cutting brass alloy.

2. Background of the Invention

Copper has excellent electrical conductivity and environmental friendliness, and bacteria harmful to the human can't survive on its surface. Other elements are added into copper, so as to improve its performance. For example, the addition of lead into the brass alloy containing copper and zinc significantly improves the cutting performance of the brass. However, brass with a high lead content will pollute the environment during its application. Especially in various valves, faucets, or the like for a water supply system, lead tends to dissolve in the water, which has serious damage to human health.

In addition, the environmental problem is increasingly outstanding, and the working environment is becoming more serious. As a result, the surface strength of brass products is reduced, and the brass tube may even perforate. This greatly reduces the lifetime of brass products and causes problems in application.

Therefore, there is a need to provide an alloy formula for solving the above problems, which can replace the brass with a high lead content, is dezincification corrosion resistant, and further has excellent casting performance, forgeability, cutting performance, corrosion resistance and mechanical properties.

BRIEF SUMMARY OF THE INVENTION

It is an object of the invention to provide a brass alloy which exhibits excellent performance like tensile strength, elongation rate, dezincification resistance and cutting performance, which is suitable for cutting processed products that require high strength and wear resistance. The brass alloy of the invention can securely replace the alloy copper with a high lead content, and can completely meet the demands about restrictions on lead-containing products in the development of human society.

To achieve the above object, the inventors have proposed the following low-lead brass alloy.

A low-lead brass alloy (hereinafter referred to as the inventive product 1) comprises: by the total weight of the brass alloy, 59-61 wt % copper, 0-0.1 wt % lead, 0.5-1.3 wt % bismuth, and a balance of zinc.

In the inventive product 1, the content of lead is reduced to 0.1 wt % or less, the content of copper is maintained at 59-61 wt %, and bismuth is added to form cutoff points in the alloy structure, thus increasing cutting performance of the brass alloy. On one hand, bismuth can not play its role effectively if the content of bismuth is relatively low. On the other hand, thermal cracking is prone to occur during forging of the brass alloy when the content of bismuth is relatively high, which is not conducive for producing. Thus, the content of bismuth is maintained at 0.5-1.3 wt %.

A low-lead brass alloy (hereinafter referred to as the inventive product 2) comprises: by the total weight of the brass alloy, 59-61 wt % copper, 0-0.1 wt % lead, 0.5-1.3 wt % bismuth, one or more elements selected from the group consisting of 0-0.1 wt % iron, 0-0.05 wt % aluminum, 0-0.2 wt % tin, and 0-0.3 wt % nickel by the total weight of the brass alloy, and a balance of zinc.

As compared with the inventive product 1, the inventive product 2 is further added with 0-0.1 wt % iron, 0-0.05 wt % aluminum, 0-0.2 wt % tin, and/or 0-0.3 wt % nickel. Iron is added for the purpose of enhance toughness of the alloy. Aluminum and tin are added for the purpose of further improving cutting performance of the alloy. Besides, aluminum can also increase strength, wear resistance, cast flowability, and oxidation resistance at high temperature of the alloy. Nickel can prevent the alloy from rusting. It is noted that a relatively high content of iron, aluminum, tin, and nickel will affect polishing performance of the alloy. Therefore, in order to produce a brass alloy with excellent performance, the content of iron, aluminum, tin, and nickel is 0.1 wt %, 0.05 wt %, 0.2 wt %, and 0.3 wt % or less, respectively. Whether iron, aluminum, tin, and nickel is added depends on the requirements for performance during actual production.

Preferably, in the inventive product 2, a total content of iron, aluminum, tin, and/or nickel is not less than 0.1 wt % by the total weight of the brass alloy, thus producing the inventive product 3.

More preferably, a total content of iron, aluminum, tin, and/or nickel is not more than 0.5 wt % by the total weight of the brass alloy, thus producing the inventive product 4.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The technical solutions of the invention will be described expressly by referring to embodiments thereof.

It is not intended to limit the scope of the invention to the described exemplary embodiments. The modifications and alterations to features of the invention as described herein, as well as other applications of the concept of the invention (which will occur to the skilled in the art, upon reading the present disclosure) still fall within the scope of the invention.

In the invention, the wording “or more”, “or less” in the expression for describing values indicates that the expression comprises the relevant values.

The term “and/or” as used herein should be read as “any one or more” of the elements which are connected with this term. Namely, in some case these elements can exist separately.

The dezincification corrosion resistant performance measurement, as used herein, is performed according to AS-2345-2006 specification in the cast state, in which 12.8 g copper chloride is added into 1000 C.C deionized water, and the object to be measured is placed in the resulting solution for 24 hr to measure a dezincification depth.

⊚ indicates a dezincification depth of less than 350 μm; ◯ indicates a dezincification depth between 350 μm and 400 μm; and x indicates a dezincification depth larger than 400 μm.

The cutting performance measurement, as used herein, is performed in the cast state, in which the same cutting tool is adopted with the same cutting speed and feed amount. The cutting speed is 25 m/min (meter per minute), the feed amount is 0.2 mm/r (millimeter per number of cutting edge), the cutting depth is 0.5 mm, the measurement rod has a diameter of 20 mm, and C36000 alloy is taken as a reference. The relative cutting rate is derived by measuring the cutting resistance.

The relative cutting rate=cutting resistance of C36000 alloy/cutting resistance of the sample.

⊚ indicates a relative cutting rate larger than 85%; and ◯ indicates a relative cutting rate larger than 70%.

Both the tensile strength measurement and the elongation rate measurement, as used herein, are performed in the cast state at room temperature as an elongation measurement. The elongation rate refers to a ratio between the total deformation of gauge section after elongation ΔL and the initial gauge length L of the sample in percentage: δ=ΔL/L×100%. The reference sample is a lead-containing brass with the same state and specification, i.e., C36000 alloy.

According to measurement, the proportions for constituents of C36000 alloy mentioned above are listed as follow, in the unit of weight percentage (wt %):

copper
zinc
bismuth
antimony
manganese
aluminum
tin
lead
iron

Material No.
(Cu)
(Zn)
(Bi)
(Sb)
(Mn)
(Al)
(Sn)
(Pb)
(Fe)

C36000 alloy
60.53
36.26
0
0
0
0
0.12
2.97
0.12

Embodiment 1

Table 1-1 lists inventive products 1 with 5 different constituents, which are respectively numbered as 1001-1005, each constituent being in the unit of weight percentage (wt %).

TABLE 1-1

No.
copper (Cu)
zinc (Zn)
lead (Pb)
bismuth (Bi)

1001
59.650
39.653
0.055
0.640

1002
60.305
39.093
0.100
0.500

1003
61.000
37.748
0.000
1.250

1004
59.000
39.618
0.080
1.300

1005
60.032
39.028
0.093
0.845

Measurements about cutting performance, dezincification corrosion resistant performance, tensile strength, and elongation rate are performed on alloys with the above constituents in the cast state at room temperature, and the reference sample is a lead-containing brass with the same state and specification, i.e., C36000 alloy.

Results of the measurements about tensile strength, elongation rate, cutting performance, and dezincification corrosion resistant performance are listed as follow:

TENSILE
ELON-

RELATIVE

STRENGTH
GATION
DEZINCIFICATION
CUTTING

No.
(N/mm²)
RATE (%)
LAYER
RATE

1001
297
10
⊚
⊚

1002
308
11
⊚
⊚

1003
293
10
⊚
⊚

1004
317
12
⊚
⊚

1005
310
12
⊚
⊚

C36000
394
9
◯
⊚

alloy

Embodiment 2

Table 2-1 lists inventive products 2 with 5 different constituents, which are respectively numbered as 2001-2005, each constituent being in the unit of weight percentage (wt %).

TABLE 2-1

bis-

alu-

copper
zinc
lead
muth
iron
minum
tin
Nickel

No.
(Cu)
(Zn)
(Pb)
(Bi)
(Fe)
(AL)
(Sn)
(Ni)

2001
60.340
38.858
0.100
0.500
0.000
0.050
0.150
0.000

2002
59.000
39.684
0.085
0.854
0.100
0.020
0.000
0.255

2003
60.221
38.286
0.000
1.110
0.051
0.000
0.200
0.130

2004
59.870
32.662
0.013
1.300
0.085
0.000
0.132
0.300

2005
61.000
37.438
0.050
0.995
0.080
0.040
0.143
0.252

Results of the measurements about tensile strength, elongation rate, cutting performance, and dezincification corrosion resistant performance are listed as follow:

TENSILE
ELON-

RELATIVE

STRENGTH
GATION
DEZINCIFICATION
CUTTING

No.
(N/mm²)
RATE (%)
LAYER
RATE

2001
318
11
⊚
⊚

2002
307
12
⊚
⊚

2003
300
11
⊚
⊚

2004
299
10
⊚
⊚

2005
308
10
⊚
⊚

C36000
394
9
◯
⊚

alloy

Embodiment 3

Table 3-1 lists inventive products 3 with 5 different constituents, which are respectively numbered as 3001-3005, each constituent being in the unit of weight percentage (wt %).

TABLE 3-1

bis-

alu-

copper
Zinc
Lead
muth
Iron
minum
Tin
Nickel

No.
(Cu)
(Zn)
(Pb)
(Bi)
(Fe)
(AL)
(Sn)
(Ni)

3001
59.145
39.963
0.000
0.670
0.000
0.050
0.155
0.015

3002
59.000
40.104
0.006
0.500
0.054
0.034
0.000
0.300

3003
60.240
38.370
0.065
1.112
0.011
0.000
0.200
0.000

3004
61.000
37.081
0.100
1.300
0.100
0.050
0.112
0.255

3005
60.081
38.327
0.073
1.000
0.095
0.025
0.181
0.216

Results of the measurements about tensile strength, elongation rate, cutting performance, and dezincification corrosion resistant performance are listed as follow:

TENSILE
ELON-

RELATIVE

STRENGTH
GATION
DEZINCIFICATION
CUTTING

No.
(N/mm²)
RATE (%)
LAYER
RATE

3001
295
10
⊚
⊚

3002
309
11
⊚
⊚

3003
308
10
⊚
⊚

3004
319
12
⊚
⊚

3005
320
12
⊚
⊚

C36000
394
9
◯
⊚

alloy

Embodiment 4

Table 4-1 lists inventive products 4 with 5 different constituents, which are respectively numbered as 4001-4005, each constituent being in the unit of weight percentage (wt %).

TABLE 4-1

bis-

alu-

copper
zinc
Lead
muth
Iron
minum
Tin
Nickel

No.
(Cu)
(Zn)
(Pb)
(Bi)
(Fe)
(AL)
(Sn)
(Ni)

4001
60.145
38.496
0.043
0.855
0.044
0.000
0.200
0.215

4002
61.000
38.039
0.000
0.500
0.100
0.004
0.055
0.300

4003
59.855
39.023
0.050
0.950
0.070
0.050
0.000
0.000

4004
59.000
39.368
0.032
1.300
0.085
0.013
0.100
0.100

4005
60.050
38.644
0.100
1.000
0.000
0.011
0.088
0.105

Results of the measurements about tensile strength, elongation rate, cutting performance, and dezincification corrosion resistant performance are listed as follow:

TENSILE
ELON-

RELATIVE

STRENGTH
GATION
DEZINCIFICATION
CUTTING

No.
(N/mm²)
RATE (%)
LAYER
RATE

4001
302
29
⊚
⊚

4002
310
19
⊚
⊚

4003
303
10
⊚
⊚

4004
318
12
⊚
⊚

4005
319
11
⊚
⊚

C36000
394
9
◯
⊚

alloy

Although the invention has been described with respect to embodiments thereof, these embodiments do not intend to limit the invention. The ordinary skilled in the art can made modifications and changes to the invention without departing from the spirit and scope of the invention. Thus, the protection of the invention is defined by the appended claims.

LOW-LEAD BRASS ALLOY

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Abstract

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Priority Claims (1)