KR101151278B1 - Methods and apparatuses of x-ray generation driven by pyroelectric crystals using solar radiation - Google Patents

Abstract

The present invention is a method and apparatus for generating X-rays by accelerating electron beams due to the potential difference between the surface charge induced on both sides of the crystal and the X-ray target by irradiating solar heat to the pyroelectric crystal. By irradiating sunlight to induce a temperature change of the pyroelectric crystal increases the potential difference to generate a high-energy electron beam and generate X-rays using the same.

Description

X-Ray Generator Driven by Pyroelectric Crystals using Solar Radiation

The present invention relates to an apparatus for generating a pyroelectric crystal due to solar heat, and in particular, to irradiate the pyroelectric crystal with solar heat to minimize temperature deviation in the longitudinal direction and the axial direction of the pyroelectric crystal and to induce surface charge to generate X-rays. It's about letting devices.

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Pyroelectric phenomenon is a phenomenon in which spontaneous crystals are cut in a direction perpendicular to the polarization direction, and a certain heat is applied to the crystals to induce spontaneous polarization by inducing surface charges having different polarities on both sides of the crystal.
Pyroelectric crystals, which are anisotropic crystals, are polarized at equilibrium and have a total dipole moment even in the absence of an external electric field. When the pyroelectric crystal is cut in a direction perpendicular to the polarization direction, surface charges having different polarities are induced at both ends of the cut surface, and thus spontaneous polarization (P _s ) exists in the absence of an external electric field or temperature change. When heat is applied to such a pyroelectric crystal, a change in spontaneous polarization (ΔP _s ) occurs when a temperature change is induced, which is called a pyroelectric effect. The pyroelectric effect forms an electric field large enough to emit electrons or generate effective radiation. The electric field is proportional to the surface charge induced. The magnitude of the surface charge per unit area is given by ΔP _s = γΔT when the pyroelectric crystal is heated. Where γ is the pyroelectric constant and the temperature change of the ΔT pyroelectric crystal. It can be seen that the surface charge induced in the pyroelectric crystal increases in proportion to the temperature change.
Since the surface charge of the pyroelectric is multiplied by the cross-sectional area, the total charge of the cross-section of the pyroelectric crystal is Q = γΔTA, where A is the cross-sectional area. The potential difference due to the surface charge thus induced is V = Q / C.

The magnitude of the electric field in a device composed of pyroelectric crystals and targets

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Also, in a device where two pyroelectric crystals are arranged to induce different charges, the magnitude of the electric field

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As shown in Equation 1, the electric field formed by the pyroelectric crystal increases as the distance between the pyroelectric crystal and the target becomes shorter (d _gap ), and the distance between the two crystals as shown in Equation 2 (D _gap ) The closer it is, the longer the length (L) of the pyroelectric crystal and the larger the temperature change, the greater the induced electric field.

In order to induce charge on the cross-section of the pyroelectric crystal, the heat conductivity of the pyroelectric crystal during heating or cooling must be large to facilitate heat transfer. However, the thermal conductivity of a typical pyroelectric crystal is 45 mJ / cm-sec for LiTaO ₃ , which is similar to that of glass fiber used for building insulation. In general, other than the second electric crystal LiTaO ₃ also has a thermal property similar to the LiTaO _3. Due to the thermal characteristics of the above-mentioned superelectric crystals, the heat source contact end surface and the opposite surface when heated by a resistance heating or a thermal conduction method using a thermoelectric cooling device (TEC), which is a method of heating a pyroelectric crystal used in the prior art. It causes a large temperature deviation.

Pyroelectric crystals with low heat capacity and low thermal conductivity have a large temperature deviation between the heat source contact cross section and the opposite cross section, so that in case of more than a certain size of the pyroelectric crystal, the surface charge induction does not increase or decrease in proportion to the temperature rise. .
In other words, the conventional method of heating a pyroelectric crystal is a contact method by resistance heating and a thermoelectric effect device (TEC). Since heat transfer depends on heat conduction, the heat source contact surface between the heat source contact surface and the opposite surface of the pyroelectric crystal having small heat capacity and thermal conductivity is different. The longer the temperature deviation of, the larger the pyroelectric crystal length is. Such a temperature deviation may cause a significant slowdown in the potential difference or decrease in the potential difference when the pyroelectric crystal is about 10 mm or more in length.
In the prior art, a method of arranging two pyroelectric crystals, one of the methods used as a method for doubling an induction electric field, facing the cross section of a crystal having opposite polarity of surface charge is applied. In this case, as shown in Equation 2, the electric field induced by the pyroelectric crystal is closer to the distance between two opposing crystals ( d _gap ), the wider the cross-sectional area (A) of the pyroelectric crystal and the longer the length (L). However, the larger the temperature change, the larger the induced electric field.The conventional superelectric crystal heating method is a contact method by resistance heating, and since the heat transfer depends on the thermal conductivity, the heat source contact surface of the superelectric crystal having low thermal conductivity is opposite to the opposite surface. The longer the temperature difference between the pyroelectric crystals, the greater the deviation. This increase in temperature results in a significant slowdown of the increase in potential difference or a decrease over a certain length.

The X-ray generator according to the present invention is to overcome such a problem, and to prevent the reduction in the potential difference due to the temperature deviation in the pyroelectric crystal by using the sunlight as a clean infinite energy source in the X-ray generator.

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In order to increase the size of the pyroelectric crystal or to facilitate the construction of the device for the purpose of increasing the potential difference of the pyroelectric crystal device due to heat induction and improving the performance of the X-ray generator, the thermal conductivity method used in the prior art is a superconducting method. It is difficult to reduce the temperature deviation of both sections of the electric crystal. The present invention can overcome the limitations of the prior art and relates to a method and apparatus for generating X-rays by solar irradiation, which is clean infinite energy.
In this method of heating by solar irradiation, radiant heat penetrates into the inside of the pyroelectric crystal during solar irradiation and simultaneously heats the inside and the outside of the pyroelectric crystal, thereby minimizing the temperature deviation in the longitudinal direction and the axial direction of the pyroelectric crystal. Provided is an X-ray generator capable of efficient surface charge induction.

 The X-ray generator according to the present invention uses a heat transfer method by radiation instead of heat conduction in the pyroelectric crystal. A non-contact method of irradiating a pyroelectric crystal with a radiant heat source focused on sunlight, and measures the temperature variation in the longitudinal axis direction of a pyroelectric crystal of about 20 mm or more longer than the length used in the prior art or a pyroelectric crystal connected in series in the longitudinal direction. Overcoming the limitations of the prior art by minimizing and heating.

X-ray generators using sunlight generate X-rays using solar energy, which is infinite energy, and will be applied to a wide range of applications in the future. In addition, when the temperature of the pyroelectric crystal is increased by irradiating solar heat to the pyroelectric crystal, the surface of the pyroelectric crystal has a long length and a wide cross-sectional area. The charge increases, which results in an increase in the electric field. Increasing the electric field can improve the electron and ion acceleration performance can greatly improve the X-ray generation, performance using this device.

1 is a view schematically showing a pyroelectric crystal X-ray generator by solar irradiation according to the present invention;
2 is a view schematically showing a pyroelectric crystal X-ray generator by a conventional resistance heating method, and
3 is a transfer simulation diagram of a solar beam irradiated to a pyroelectric crystal by a parabolic reflective surface according to another embodiment of the present invention.

In order to improve the performance to the application level, it is necessary to increase the induced surface charge for the practical use of the high energy generator by the pyroelectric crystal. In order to increase the surface charge, there is a method of increasing the temperature change of the pyroelectric crystal or increasing the cross-sectional area and length.

Figure 2 shows an example of the X-ray generator by the resistance heating method of the prior art. In the related art, when the length and cross-sectional area of the pyroelectric crystal 10 are increased, the induction of surface charge can be increased. However, when the length of the pyroelectric crystal 10 is increased, the pyroelectric crystal 10 is in contact with the heat source 60 due to the temperature characteristic. The difference in temperature between the face and the face that is not will increase. This temperature deviation causes the number of surface charges to increase no more than a certain length. As a result of the current study, it is reported that the surface charge does not increase over a length of 10 mm. In addition, when the cross-sectional area is increased, a temperature difference between the surface of the pyroelectric crystal and the center of the pyroelectric crystal is generated, and as a result, the increase in the surface charge is slowed down so that the generated energy does not increase even if the length of the pyroelectric crystal is longer than 10 mm. Therefore, the X-ray energy also does not increase.

Hereinafter, with reference to the drawings will be described in more detail the configuration of the present invention. 1 (a) is a front view showing an embodiment of the X-ray generating apparatus according to the present invention, Figure 1 (b) is a side view showing an embodiment of the X-ray generating apparatus according to the present invention, and Figure 3 is the present invention In one example is a transcriptional representation of the solar beam.
As shown in FIG. 1, the X-ray generator according to the present invention includes a pyroelectric crystal 10, a container having an inner surface thereof with a reflective surface 30, a cooling fluid 40, an X-ray transmission window 20, and an X-ray target ( 25), the solar transmission window 50, the solar block plate 60.
As shown in FIG. 1 (a) and (b), the container in which the pyroelectric crystal 10 is installed reflects and refracts incident sunlight 70 having an inner surface formed of a reflective surface 30. The container may also be formed in a semi-cylindrical shape as shown in Figures 1 (a) and (b). In addition, the container may be formed in a double so that the cooling fluid 40 can enter. As shown in FIG. 1, the semi-cylindrical reflection surface 30 has a parabolic cross section so that sunlight is more efficiently reflected and / or refracted to irradiate the pyroelectric crystal 10 in multiple directions. You can. The container is sealed by the solar transmission window 50 so that the sunlight 70 can freely enter the inside of the container. The solar panel 60 may be installed on the solar transmission window 50 to block the sunlight 60 when cooling is required.
As shown in FIG. 1B, an X-ray target 25 and an X-ray transmission window 20 are formed on one side of the container, and the charge 80 emitted from the heated pyroelectric crystal 10 is transferred to the X-ray target 25. The collision generates X-rays, and the generated X-rays are radiated to the outside through the X-ray transmission window 20.
That is, sunlight 70 enters the container through the solar transmission window 50, and partly irradiates the pyroelectric crystal 10, and part of the sunlight 70 reflects the surface 30 constituting the container. The pyroelectric crystal 10 is irradiated by reflection and / or refraction at. The pyroelectric crystal 10 radiates heat inside and outside the pyroelectric crystal 10 by radiating heat transmitted by the pyroelectric crystal 10 by the sunlight 70 refracted and reflected by the direct irradiation and reflecting surface 30. Thus, the pyroelectric crystal with low thermal conductivity can be uniformly heated in the longitudinal direction and the axial direction.
Charges induced in the cross section of the heated pyroelectric crystal 10 aggregate on the surface to form a high potential difference, and these charges are radiated toward the X-ray target 25 to collide with the X-ray target to generate X-rays. At this time, the thickness of the X-ray target 25 is several micrometers. It has different values depending on the thickness of the target, the induced potential difference and the target material.
Operation of the X-ray generator according to the present invention configured as described above is as follows. Place the pyroelectric crystal 10 inside the vessel and open the solar panel 60 to irradiate the sunlight 70 while maintaining the vacuum degree of 10 ^-4 to 10 ^-3 Torr. It is heated by sunlight 70 directly on the electrical crystal 10 or reflected on the reflecting surface 30. The temperature of the pyroelectric crystal increases from room temperature to 110 degrees Celsius. At this time, the temperature difference between the two end surfaces of the pyroelectric crystal 10 is much smaller than the temperature difference between the two end surfaces of the crystal when heated by the contact heating source 100 applied in the prior art as shown in FIG. Minimizing the temperature deviation of both ends of the pyroelectric crystal leads to surface charge more effectively when the crystal length is increased. As a result, the heating method by the radiant heat increases the electric field formed by the pyroelectric crystal in proportion to the increase in the length of the crystal, increases the acceleration voltage, and greatly improves the performance of the X-ray generator using the same.
The method of cooling the pyroelectric crystal is carried out by a forced cooling method by attaching a solar blocking plate 60 to block the sunlight if necessary and flowing a cooling fluid 40 between the solar reflection surfaces formed in duplicate.

3 shows a form in which sunlight is focused on a pyroelectric crystal by a parabolic reflective surface by computer simulation. The shape of the reflecting surface of the container may select a form in which sunlight is best focused on the pyroelectric crystal 10.
In the X-ray generator according to the present invention configured as described above, since radiant heat is transmitted to the pyroelectric crystal by the heating method by solar irradiation, the pyroelectric crystal having low thermal conductivity is heated in the longitudinal direction and the axis by simultaneously heating the inside and the outside of the pyroelectric crystal. It can be heated uniformly in the direction to overcome the size limitations of the pyroelectric crystals to increase the surface charge induction, thereby obtaining a high potential difference to generate X-rays with better efficiency and to generate X-rays using natural energy.

10: pyroelectric crystal
20: X-ray radiation window
25: X-ray target
30: solar reflective surface
35: vacuum container
40: cooling fluid
50: solar transmission window
60: solar blocking plate
70: sunlight
80 electron beam
90 X-ray
100: resistance heating device

Claims (3)

In the X-ray generator,
An X-ray transmissive window is installed at one side in an open container shape, an X-ray target is attached to an inside of the X-ray transmissive window, and an inner surface thereof is formed as a solar reflective surface, and the open upper part may receive sunlight. A container which is sealed with a solar transmission window so that it may be; And
And a pyroelectric crystal disposed inside the container such that one cross section cut and cut perpendicular to the polarization axis faces the X-ray target. The method of claim 1,
The solar reflecting surface is a x-ray generator, characterized in that the longitudinal side cross-section is parabolic. The method of claim 1,
The container is a dual structure, the inner surface of the solar reflection surface is deposited, the X-ray generating apparatus, characterized in that the cooling fluid passes through the inside of the dual structure.

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