In [3], an argon-arc method was used for fusion of compacts from chips of titanium alloys VTZ-I in a graphite or copper water-cooled mold with diameter 30 mm, height 15 mm, and weight 25 g. Conventional argon-arc welding technology was used for fusion of chip compacts into a mass: a welding transformer with current 300-500 A and a Grad-400 burner with a nonconsumable strong-shielded tungsten electrode. The technique that was used for sample preparation for analysis definitely decreased significantly the speed of the atomic-t emission method (because of the need to melt a special mass of relatively large weight~. At the same time, in this case the composition of the mass changed with increasing melting time (for contents of Mn, AI, Cr, Sn, etc.). A patent [4] is known concerning the use of an argon arc for fusion of small steel parts (rivets, pins, wire, springs, nuts, etc.) into a mass with weight 32 g, diameter 32 mm, and height 4 mm, which served as the sample. Remelting was carried out in a special vacuum unit in an argon-filled chamber. The power supply was three-phase 415 V, and the maximum linear current was 45 A. Twelve masses could be melted in a single loading. However, the existing methods do not make it possible to obtain a metallic sample for atomic-emission analysis of nonmonolithic metallic materials with weight less than 20 g. In addition, it is not possible to avoid completely changes in the chemical composition of a sample as a result of distillation and during occurrence of chemical reactions without the use of a rotating magnetic field for movement of the electric arc over the sample surface at a specific optimal rate. A method for atomic-emission analysis and a method for preparation of cast low-weight (0.5-1 g) samples of nonmonolithic titanium are not known. At the same time, in practice it is often necessary to analyze samples of low-weight nonmonolithic titanium.In the, present paper, we carried out investigations and developed a simple method [5] and prepared design documentation for a device (Figs. 1 and 2) for melting of samples of nonmonolithic metals weighing 0.05-1.0 g with retention of the original chemical composi