JPS60198100A - Target for generating neutron - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

Detailed Description of the Invention (Industrial Application Field) The present invention relates to a lithium target for bombardment with protons for producing neutrons by the Li(p,n): Be reaction, and The present invention relates to a device for detecting the presence of a predetermined substance in ore using neutron radioactivity.

(Conventional technology) Conventional all-ore sorting plants require the sorting of tens of tons of ore every hour, so rapid analytical technology is needed.
Must be done.

A conventional preferred technique is “7Au(n,n′ y )19
This is a neutron activation analysis that uses the 7"'Au reaction to activate the gold present in the lump ore. The 197""Au nuclide thus produced has a half-life of approximately 7.8 seconds and is 279"
It decays by emitting gamma rays with an energy of K e V.

British Patent Nos. 2055465B and 2101304A
(corresponding U.S. Pat. Nos. 4,340,443 and 198)
U.S. Patent Application No. 383,686 filed on May 27, 2017) describes a method in which lump ore is activated by the above reaction, and the continuously emitted γ-rays are detected and analyzed to evaluate the gold content in the ore. An apparatus for sorting gold-containing ores is disclosed.

Such ore beneficiation plants require intense sources of fast neutrons to cause activation. An example of a radiation source is a target consisting of a lithium layer coated on a silver backing plate and bombarded with protons.

However, the effect of the bombardment is to generate heat and hydrogen within the target. This is harmful to the target structure. For example, in the target described above, hydrogen bubbles tend to form an interface between lithium and silver.

(Means for Solving the Problems) According to the present invention, a target comprising at least one lithium foil and for generating neutrons by bombardment with protons, and a structure supporting the foil in a vacuum beam tube. A structure is provided that is bombarded by a proton beam and includes at least one gap, a portion of the foil bridging the gap, and a vacuum on both sides.

When using the target, the proton beam may be incident on the foil bridging the gap at least most of the time.

In a preferred embodiment, the lithium foil is supported substantially near the end wall of the beam tube. This end wall may be made of a material with a low cross-sectional area for the neutrons from the foil. Through this end wall, hydrogen diffuses sufficiently quickly to prevent hydrogen build-up in the beam tube. The end walls may be made of palladium and heated to ensure rapid diffusion of hydrogen.

In a preferred embodiment, the support structure includes a provision defining at least one generally annular gap. The foil is
It is supported on each side of the gap or on each side of the plurality of gaps, and bridges the gap or the plurality of gaps.

The present invention provides high-energy targets that are less susceptible to damage than conventional targets and, because of the well-defined lithium thickness, are capable of producing neutrons with particularly well-defined energies. As a source of neutrons, we provide a working Targera 1-.

The invention also provides an irradiation device for irradiating lump ore in order to detect the presence of a predetermined substance in the lump ore, the irradiation device comprising a lithium target as defined above as a neutron source. It is.

(Example) Referring to FIG. 1, the total ore classification device includes a rock crusher classifier (2) that supplies rocked ore. In this crusher am(2), the ore is crushed into lumps.

From this crusher classifier (2), a flow of lumps corresponding to a mesh size of about 75 mm appears, and a flow of lumps corresponding to a mesh size of about 35 mm appears.
Chunks smaller than a mesh size of are rejected.

A stream of these masses enters the irradiation chamber (4) adjacent to the lithium target. This will be explained in detail later.

All the clumps are then sent to the gamma detector (6).

This detector (6) is provided to detect gamma rays having an energy of 2'79 KeV resulting from the decay of the 1941'' Au nuclide and to indicate the presence of gold in the ore.

Each lump of ore is individually interrogated by a detector (6) to determine whether its gold content is above a predetermined concentration. The critical concentration is particularly between 0.5 ppm and 5 ppm.
is within the range of - In the example, it is ippm.

Each gold nugget enters a sorting device (8) arranged by a cable (7) which responds to signals from a detector (6) and separates each nugget to a predetermined total concentration in the nugget. Depending on whether the concentration is above or below, it is sorted into one of two output streams.

The crusher classifier (2) and the sorting device (8) may be well known to those skilled in the art. Moreover, the detector (6) is
Although preferably disclosed in the above specification, the crusher classifier (2), the sorting device (8) and the detector (6) are not the object of the present invention.

Referring to Figures 2 and 3, a lithium target (5) is placed at one end of the vacuum beam tube (10).

During operation of the apparatus of FIG. 1, a IIIA beam of 4,5 M e V protons passes through the vacuum beam tube (10).

The target (5) is an aluminum circular support plate (1
2). This support plate (12) consists of an inner hub (14) connected by three equally spaced radially extending struts (20) and three concentric rings (16). and an outer ring (18). Thereby, four concentric gaps (24) in the shape of a ring are defined below the strut (20).

One of the struts (20) is coupled to the hub (14). The four gaps (24) are each bridged by four annular lithium foils (30). The foil (30) has a width of 30+nm and a thickness of 0.3nwn.
and is attached to one side of the support plate (12).

A small hole (32) provided in the center of the hub (4) is inserted into the support plate (4).
12) The pressure difference between the two sides is eliminated. The support plate (12) is attached to the inner peripheral wall surface of the beam tube (10).

5 pipes (34) (35) (36) (37)
(38) are concentrically weighted on the hub (14), the three rings (16) and the outer ring (18), respectively. Pipe (34) (35) (36) (
37) (38) extends in the radial direction, and its end protrudes from the wall of the beam tube (10).

The radially extending portions of the pipes (34) (35) (36) are arranged with the struts (20).

At the end of the f-beam tube (10) as shown in FIG.
) is provided with a thickness sufficient to withstand a pressure difference of 1 atmosphere. Copper end plate (44
) is provided all around the rim (42). The copper end plate (44) has a duct h (48) on the diametrically opposite part.
It has two inlets (46) connected to.

During operation of the apparatus of FIG.
) downwards towards the target (5) is accelerated and scanned around each lithium foil (30) while swinging. At the same time, tubes (34) (35) (36) (3
7) A coolant such as water is passed through (38) to prevent the temperature of lithium from reaching its melting point of 186°C.

By sending air through the duct (48), air is introduced into one side of the palladium plate (40), from which excess heat is extracted.

As a result of the nuclear reaction of g L i (p, n) XB e, about 0,6 M e V and 2,8 M e
A strong flow of energetic neutrons is generated between V and irradiates the lump ore passing through the adjacent irradiation chamber (4) shown in the first diagram.

The thickness of the lithium foil (30) and the energy of the incident protons define the energy range of the divergent neutrons.

The transverse section for activating the gold nucleus "7Au is at most about 2.5 M e V, and also 0.6 M e V.
Neutron energies between e V and 2.8 M e V perform this activation.

However, 0,6 M e V and 2,8 M e V
The energy between (
r++p) is insufficient to cause activation by reaction.

Examples of other elements include aluminum and silicon. Neutrons with energies below about 0.6 M e V cannot activate all nuclei. However, activation by (n, γ) reactions such as aluminum can occur, which is not desirable.

In this example, the thickness of the foil (30) is 0.3 m;
This can be determined by considering the above. Since there is a vacuum on both sides of the foil (30), the foil (30) bridging the gap (24)
Part 0) is required to support only its own weight.

The protons that do not undergo the above reaction by lithium protons are approximately 3
, 3 M e 'V from the lithium foil (30) and incident on the palladium plate (40). In this palladium plate (40) the energy is dissipated due to the heat due to collisions with the palladium lattice.

The palladium plate (40) is thus heated and its temperature is controlled by the air flow from the duct (48).

The hydrogen atoms, like decelerated protons, rapidly diffuse through the hot palladium plate (40) and are removed into the air stream.

Since the lithium foil (30) is spaced apart from the palladium plate (40) by about 201 m, the palladium plate (40) may be heated to a temperature equal to or higher than the melting point of lithium. Heat transfer across the gap occurs only by thermal radiation.

The diffusion rate of hydrogen through the palladium plate (40) is:
greater than the velocity of the palladium plate (40) kept at low temperature. Also, the plate (40), although only mentioned with respect to palladium, may be other metals, such as niobium, through which hydrogen diffuses at a sufficiently fast rate.

[Brief explanation of drawings]

1 is a block diagram of a total ore sorting device having a lithium targeter 1 according to the present invention; FIG. 2 is a sectional view of the lithium target of FIG. 1; FIG. 3 is an arrow A in FIG. 2; FIG. 2 is a diagram of a lithium target viewed from the direction of FIG. (2) Crusher classifier (4) Irradiation chamber (5) Lithium target (6) Detector (8) Sorting device (
1o) Vacuum beam tube (12) Support plate (14) Inner hub (16) Ring (18) Outer ring (20) Strut (24) Gap (30) Foil (32) Small hole (34) (35) <36 ) (37) (38) Pipe (40) Palladium plate (42) Rim (44) Body end plate (46) Entrance (48) Duct drawing (no change in content) Fr3.2 Purpose 9, 3 Procedure Amendment against illusion dated April 1985 by Manabu Shiga, Commissioner of the Japan Patent Office■, Indication of the case, Patent Application No. 252026, filed in 1982, No. 2
, title of the invention Target 3 for generating neutrons,
Relationship with the case of the person making the amendment Patent applicant name General Mining Union Corporation Limited (3) Specification (4) Drawings

Claims (9)

[Claims] (1) having at least one lithium foil (5);
A target for generating neutrons by proton bombardment, comprising a support (12) supporting a foil (5) in a vacuum beam tube subjected to bombardment by a proton beam, and this support (12) having a small Both have one gap (24), and the foil (
30) A target for producing neutrons, characterized in that a part bridges the gap (24) and is exposed to a vacuum on both sides thereof. (2) The lithium foil (30) is attached to the end wall (4) of the beam tube.
0), this end wall (40) is made of a material with a low cross-sectional area for the neutrons from the hole, through which the hydrogen can diffuse sufficiently rapidly. The target for generating neutrons according to claim 1, wherein the target is adapted to prevent hydrogen build-up within the beam tube. (3) The target for generating neutrons according to claim (2), wherein the end wall (40) is made of palladium. (4) Claims (2) or (3) further include a device (48) (44) for heating the end wall (40) so that hydrogen can diffuse rapidly. ) Target for producing neutrons as described in section. (5) the support (12) is a support plate (12) defining at least one generally annular gap (24), and the foil (30) bridges the one or more gaps and A target for generating neutrons according to any one of claims (1) to (4), characterized in that the target is supported on both sides of a gap. (6) The support body (12) is a device (3
4) A target for generating neutrons according to any one of claims (1) to (5), characterized by comprising (36), (37), and (38). (7) a support plate comprising a support (12) mounted in the vacuum beam near the end wall (40), the support (12) having at least one generally annular gap (24); A device (34) (
35) (36) (37) (38) and at least one foil (5) made of lithium, supported by a support and bridging the gap, by proton bombardment. Target for generating. (8) The target for generating neutrons according to claim (7), wherein the end wall (40) is made of palladium or niobium. (9) A target for generating neutrons according to claim (7) or (8), comprising devices (48) and (44) for heating the end wall. (lO) To detect the presence of a certain substance in lump ore,
An irradiation device for irradiating lump ore, the irradiation device comprising a lithium target according to any one of claims (1) to (10) as a neutron source.