Anisotropic rare earch magnet powder, method for producing the same, and bonded magnet

What is claimed is: 1 . An anisotropic rare earth magnet powder including powder particles comprising: agglomerates of R 2 TM 14 B 1 -type crystals of a tetragonal compound consisting of one or more rare earth elements (hereinafter referred to as “R”), boron (hereinafter referred to as “B”), and one or more transition elements (hereinafter referred to as “TM”), the crystals having an average crystal grain diameter of 0.05 to 1 μm, and enveloping layers containing at least neodymium (Nd) and copper (Cu), wherein surfaces of the R 2 TM 14 B 1 -type crystals are enveloped by the enveloping layers, when the whole powder particles are taken as 100 atomic % (at. %), the powder particles contain: 11.5 to 15 atomic % of total rare earth element (Rt); 5.5 to 8 atomic % of B; and about 0.05 atomic % to about 2 atomic % of Cu, wherein, the powder particles have an atomic ratio of Cu, which is a ratio of the total number of Cu atoms to a total number of atoms of Rt, falling within the range of 1 to 6%; the powder particles do not include dysprosium (Dy), terbium (Tb), holmium (Ho) and gallium (Ga), and coercivity (iHc) of the magnetic powder is more than 955 kA/m. 2 . The anisotropic rare earth magnet powder according to claim 1 , wherein, when the whole powder particles are taken as 100 atomic %, the powder particles contain a total of no more than 3 atomic % of one or more of the group consisting of Ti, V, Zr, Nb, Ni, Cr, Mn, Mo, Hf, W, Ta, Si, Zn and Sn. 3 . The anisotropic rare earth magnet powder according to claim 1 , wherein, when the whole powder particles are taken as 100 atomic %, the powder particles contain 0.1 to 10 atomic % of Co. 4 . The anisotropic rare earth magnet powder according to claim 1 , wherein, the enveloping layers comprise a diffusion layer in which are diffused into crystal grain boundaries of the R 2 TM 14 B 1 -type crystals. 5 . A method for producing the anisotropic rare earth magnet powder according to claim 1 comprising: a mixing step of obtaining a mixed raw material of a magnet raw material capable of generating agglomerates of R 2 TM 14 B 1 -type crystals of a tetragonal compound of R, B and TM, and a diffusion raw material to serve as a supply source of at least Nd and Cu; and a diffusion step of heating the mixed raw material to diffuse at least Nd and Cu onto surfaces or into crystal grain boundaries of the R 2 TM 14 B 1 -type crystals; wherein when the whole magnet raw material is taken as 100 atomic %, the magnet raw material contains an approximate theoretical composition consisting essentially of: 11.6 to 12.7 atomic % of R; 5.5 to 7 atomic % of B; and remaining atomic % of TM. 6 . The method for producing the anisotropic rare earth magnet powder according to claim 5 , wherein the magnet raw material is obtained through: a disproportionation step of causing a base alloy to absorb hydrogen and undergo a disproportionation reaction; and a recombination step of dehydrogenating and recombining the base alloy after the disproportionation step. 7 . The method for producing the anisotropic rare earth magnet powder according to claim 6 , wherein the magnet raw material is obtained further through, before the disproportionation step, a low-temperature hydrogenation step of allowing the base alloy to absorb hydrogen in a low temperature range below temperatures at which the disproportionation reaction occurs. 8 . A bonded magnet, comprising: the anisotropic rare earth magnet powder according to claim 1 ; and a resin bonding the powder particles together. 9 . An anisotropic rare earth magnet powder including powder particles comprising: agglomerates of R 2 TM 14 B 1 -type crystals of a tetragonal compound consisting of one or more rare earth elements (hereinafter referred to as “R”), boron (hereinafter referred to as “B”), and one or more transition elements (hereinafter referred to as “TM”), the crystals having an average crystal grain diameter of 0.05 to 1 μm, and enveloping layers containing at least neodymium (Nd), copper (Cu) and aluminum (Al), wherein surfaces of the R 2 TM 14 B 1 -type crystals are enveloped by the enveloping layers, when the whole powder particles are taken as 100 atomic % (at. %), the powder particles contain: 11.5 to 15 atomic % of total rare earth element (Rt); 5.5 to 8 atomic % of B; about 0.05 atomic % to about 2 atomic % of Cu; and 0.1 to 5 atomic % of Al, wherein, the powder particles have an atomic ratio of Cu, which is a ratio of the total number of Cu atoms to a total number of atoms of Rt, falling within the range of 0.6 to 11.8%; the powder particles do not include dysprosium (Dy), terbium (Tb), holmium (Ho) and gallium (Ga), and coercivity (iHc) of the magnetic powder is more than 955 kA/m. 10 . The anisotropic rare earth magnet powder according to claim 9 , wherein, when the whole powder particles are taken as 100 atomic %, the powder particles contain a total of no more than 3 atomic % of one or more of the group consisting of Ti, V, Zr, Nb, Ni, Cr, Mn, Mo, Hf, W, Ta, Si, Zn and Sn. 11 . The anisotropic rare earth magnet powder according to claim 9 , wherein, when the whole powder particles are taken as 100 atomic %, the powder particles contain 0.1 to 10 atomic % of Co. 12 . The anisotropic rare earth magnet powder according to claim 9 , wherein, the enveloping layers comprise a diffusion layer in which are diffused into crystal grain boundaries of the R 2 TM 14 B 1 -type crystals. 13 . A method for producing the anisotropic rare earth magnet powder according to claim 9 comprising: a mixing step of obtaining a mixed raw material of a magnet raw material capable of generating agglomerates of the R 2 TM 14 B 1 -type crystals of a tetragonal compound of R, B and TM, and a diffusion raw material to serve as a supply source of at least Nd and Cu; and a diffusion step of heating the mixed raw material to diffuse at least Nd and Cu onto surfaces or into crystal grain boundaries of the R 2 TM 14 B 1 -type crystals; wherein when the whole magnet raw material is taken as 100 atomic %, the magnet raw material contains an approximate theoretical composition consisting essentially of: 11.6 to 12.7 atomic % of R; 5.5 to 7 atomic % of B; and remaining atomic % of TM. 14 . The method for producing the anisotropic rare earth magnet powder according to claim 13 , wherein the magnet raw material is obtained through: a disproportionation step of causing a base alloy to absorb hydrogen and undergo a disproportionation reaction; and a recombination step of dehydrogenating and recombining the base alloy after the disproportionation step. 15 . The method for producing the anisotropic rare earth magnet powder according to claim 14 , wherein the magnet raw material is obtained further through, before the disproportionation step, a low-temperature hydrogenation step of allowing the base alloy to absorb hydrogen in a low temperature range below temperatures at which the disproportionation reaction occurs. 16 . A bonded magnet, comprising: the anisotropic rare earth magnet powder according to claim 9 ; and a resin bonding the powder particles together.