JPH0382529A - Lead sandwiching plate - Google Patents

Abstract

PURPOSE:To obtain a sandwich type composite sheet superior in sound insulating properties, vibration damping properties, weather resistance and radiation nontransmission properties, by a method wherein a lead sheet becoming a core material is rolled and joined to a pair of surface materials. CONSTITUTION:The first layer 2 comprised of electrolytic nickel-cobalt alloy plated layer is performed to one surface of a stainless steel sheet 1 becoming surface material as a joining mediation device. The second layer 3 comprised of electrolyitc lead-tim alloy plated layer is coated on the first layer 2. Either a lead sheet 4 having a desired thickness is rolled and joined onto the second layer 3 or one side surface sheet A' is comprised by rolling and joining the lead sheet 4 having the desired thickness to the one side of the stainless steel sheet 1 through the first and send layers 2, 3 by making an inside constitution of the surface sheet A' indentical with that of a surface sheet A. The other side surface sheet B' is formed by performing plated lamination of the first and second layers 2, 3 to the one side of the stainless steel sheet 1. A lead sandwiching sheet (a) is obtained by rolling and joining plating-treated sides of those surface sheets, that is, the surface sheets A, B by confronting them with the insides.

Description

[Detailed Description of the Invention] (Industrial Application Field 2) This invention has excellent sound insulation, vibration damping, weather resistance, radiation resistance, etc., and can be used stably for a long time mainly indoors such as doors, walls, partitions, etc. The present invention relates to a sandwich-type composite plate in which the intermediate layer is made of lead.

(Conventional technology 2 As a sound insulating and radiopaque material used indoors,
Although lead is pasted onto a steel plate, it is not aesthetically pleasing because the lead surface is GTT5T, and because the adhesion between the lead layer and the board is insufficient, peeling often occurs over time. On the other hand, there is no practical example of a composite plate having a ship as an intermediate layer as in the present invention.

(Problems to be Solved by the Invention) This invention eliminates the deficiencies of the above-mentioned conventional technology, is easy to process and mold, has high adhesion strength, and has functions such as sound insulation, vibration damping, and radiation resistance. The object of the present invention is to provide a lead sandwich board which is excellent in appearance and shows minimal change over time, and in which the intermediate layer sandwiched between a pair of surfaces/plates is made of lead.

(Means for Solving the Problems) The lead sandwich board of the present invention is formed by rolling and joining a lead plate serving as a core material to a pair of surface materials through a joining mediating means applied to the surface materials. be. Here, the surface material is not only a steel plate and a stainless steel plate, but also a weather-resistant material such as a copper plate and a zinc plate.

(According to the above structure, the joining medium valve means applied to the surface material is bonded to the surface material on one side, and closely bonded to the lead plate serving as the core material on the other side.

(Example) To explain this invention by an example, as shown in FIG. A first layer 2 made of a nickel-cobalt electroalloy plating layer is applied to one surface of the stainless steel plate 1 as a bonding medium, and
A second layer 3 consisting of an electrolytic lead-tin alloy layer is coated on layer 2, and a lead plate 4 of a certain thickness is rolled and joined on top of the second layer, as shown in Fig. 2. One surface plate A9 has the same internal structure as the above-mentioned surface plate A, and is formed on one side of the stainless steel plate 1! The first layer 2 and the second layer 3 are formed by rolling and joining a lead plate 4 of the required thickness through the second layer 2 and the second layer 3, and the other surface plate B' is made by laminating the first layer 2 and the second layer 3 on one surface of the stainless steel plate 1. These surface plates, that is, the plated side of the former surface plate A%B facing the inner surface and rolled and joined are the lead sandwich plate a shown in Fig. 3. The lead sandwich plate shown in FIG. 4 is obtained by rolling and joining the latter surface plates A' and B with the plated sides facing the inner surface. In this case, the thickness of the stainless steel plate 1 serving as the surface material is selected from various thicknesses ranging from 1% to the same thickness on the front and back sides, and the thickness of the lead layer or plating layer to be rolled and coated is Various heights can also be selected.

The above rolling joint is made using a two-stage cold rolling machine (roll diameter 300■φ).
], and the rolling load was 10.0 tons/10 cod.

In the above lead sandwich plate aSb, the thickness of the stainless steel plate 1 and the thickness of the lead layer to be laminated were carefully selected, and the length was 150-1<1125 to evaluate the adhesion.
A test piece of seagull was cut out and the following tests were conducted.

(1) During OT bending test rolling, the front and back steel plates are the inside and outside 2
This type of close contact bending was repeated 10 times, and the peeling state between the intermediate lead layer and the front and back steel plates was observed from the side.

(2) Salt water immersion test The test piece subjected to the above-mentioned close contact bending test was immersed in 5% salt water (40°O) for 3 weeks, and the progress of peeling at the end face was observed.

(8) Cold/heat cycle test A test piece with a length of 15011 IM and 150 m/1 m is immersed in a 12♂O hot silicone oil bath for 5 minutes, then cooled to room temperature and held for 5 minutes for 1500 cycles.
Go around and g41 at the end! The state of peeling from both front and back steel plates on the l11 side was observed.

The evaluation test results for each sample are shown in Attached Table 1.

Note that ◎ in Attached Table 1 means that no abnormality or deterioration was observed compared to before the test.

Next, the present invention will be explained with reference to another embodiment. As shown in FIG.
In both cases, the above-mentioned surface plate B° has the same thickness, that is, one surface of the stainless steel plate 1 is coated with a Ttz nickel-cobalt alloy plating with a first layer 2 that has good adhesion to the steel plate 1, and the first layer A lead-tin alloy plating having a very good affinity for lead is applied as a second layer 6 on the surface plate A″,
B" is rolled and joined with the plated side facing the inner surface and a lead plate 0 of the required thickness in the middle, that is, each of the wires wound on a payoff reel 5.6 as shown in FIG. The surface plates A'' and B'' are guided to the rolling roll 7.7 with the plating side facing outward and wound onto the take-up reel 8. During the winding, there is a contact point between the rolling rolls 7.7. The lead plate 0 wound on the payoff reel 9 is the polishing device f1
10, and is guided and inserted into the guide table 11 under predetermined cold rolling conditions (roll diameter 3
00 tons φ, rolling load 10.0/10ss), lead plate O
The lead sandwich plate d as shown in FIG. 7 is produced by cold-rolling and joining the front and back surface plates A''Be as an intermediate layer.

In the above lead sandwich plate d, stainless steel plate 1
In order to evaluate the adhesion of various board thicknesses, plating amounts, and lead board thicknesses, test pieces with a length of 150 layers and a width of 25 layers were cut out, and test pieces were cut out from the lead sandwich board a described above.
A 07 bending test, a salt water immersion test, and a thermal cycle test similar to the tests conducted on Sb were conducted, and the evaluation test results are shown in Attached Table 2. In addition, ◎ in the attached table means that no abnormality or deterioration was observed compared to before the test.

Although the sound insulation and radiation shielding effects of the above lead sandwich plates aSb and & have not been evaluated, these characteristics are uniquely dependent on the thickness of the lead layer, and the intermediate lead layer is There is no doubt that as long as the material is firmly preserved between the two surface plates as shown in the figure, it can maintain performance for a long period of time without causing any practical problems. (Effects of the Invention) As described above, this invention According to the lead sandwich board, by placing the lead layer in close contact with the intermediate layer sandwiched between the surface materials, it is possible to maintain the beauty of the front and back surfaces while minimizing deterioration over time.
O exhibits unprecedented effects such as sound insulation, vibration damping, and radiation shielding.

[Brief explanation of drawings]

Figures 1 and 2 are partial sectional views showing the structure of the front and back surface plates, Figures 3 and 4 are lead sandwich plates a and b.
FIG. 5 is a partial sectional view showing the structure of the lead sandwich plate d in another embodiment of the present invention, and FIG.
The figure is a side view of a schematic manufacturing apparatus for the lead sandwich plate d, and the seventh figure is a partial sectional view of the lead sandwich plate d.
1 is a stainless steel plate, 2 is the first Wj, 3Gt second layer, 4
is a lead plate, 5.6.9 is a payoff reel, 7 is a rolling roll, 8 is a take-up reel, 10 is a polishing device, and 11 is a guide table. MU1MU91MU"B-%B'B" is the surface plate, 0 is the lead plate, and aSbSd is the lead sandwich plate. Clothes 1 Table 2 7, #Salesmanship〆N2: 19 Iobliter//: ff'4 boots 5 Procedural amendment October 12, 2008 3. Person making the amendment〒 ・Relationship with the case patent

Claims (1)

[Claims] A lead sandwich plate formed by rolling and bonding a lead plate serving as a core material to a pair of surface materials via a joining mediating means applied to the surface materials.