JP2712311B2 - X-ray tube power supply - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial application field The present invention relates to various devices equipped with an X-ray tube, such as an X-ray fluorescence spectrometer and an X-ray diffractometer, and the like. The present invention relates to an X-ray tube power supply for supplying a voltage and a tube current.

(B) Conventional technology In a fluorescent X-ray analyzer, an X-ray tube diffractometer, and the like,
A power supply device for applying a tube voltage and a tube current to the X-ray tube is provided. When the apparatus is used, a high tube voltage of several tens of kv is applied to the X-ray tube by the power supply to generate X-rays.

By the way, when the apparatus is started, the tube voltage and the tube current applied to the X-ray tube are gradually increased until a desired operation state of X-ray generation is reached, and when the apparatus is stopped, the currently applied tube voltage is applied. However, it is necessary to gradually lower the tube current. That is, when a high tube voltage is instantaneously applied to the X-ray tube or a large current flows in a state where the tube voltage is low, the filament causes discharge breakdown and the like, and the life of the X-ray tube is shortened. Causes a decline. Therefore, conventionally, the tube voltage and each setting dial of the tube voltage were manually switched stepwise while checking the deflection of the meter.

(C) Problems to be Solved by the Invention However, it is not preferable to manually switch the tube voltage and the tube current because the operation is complicated and an operation error may occur.

The present invention has been made in view of such circumstances, and eliminates the complexity of the setting operation by automating the setting operation of the tube voltage to be supplied to the X-ray tube and the tube current. An object of the present invention is to make it possible to continuously switch the tube current, reduce the impact of discharge applied to a filament or the like, and improve the life of the X-ray tube as compared with the related art.

(D) Means for Solving the Problems In order to achieve the above object, the present invention provides an X-ray tube voltage adjusting means for increasing / decreasing a tube voltage applied to an X-ray tube;
The following configuration is adopted in an X-ray tube power supply device provided with an X-ray tube current adjusting means for increasing / decreasing a tube current applied to a tube tube.

That is, in the X-ray tube power supply device of the present invention, a tube voltage / tube current detecting means for detecting a tube voltage and a tube current applied to the X-ray tube, and a power (= tube) applied to the X-ray tube ON / OFF instructing means for instructing ON / OFF of (voltage × tube current), and a tube voltage detected by the tube voltage / tube current detecting means in response to a power-off instruction from the ON / OFF instructing means. Power-down schedule calculating means for creating a power-down schedule for reducing power linearly in time based on the value of the tube current, and a power-on schedule from the on / off designating means. Power-up schedule calculation means for creating a power-up schedule for increasing power linearly with time based on the values of the tube voltage and the tube current detected by the voltage / tube current detection means, Times for outputting a control signal for increasing / decreasing a tube voltage to the X-ray tube voltage adjusting means and outputting a control signal for increasing / decreasing a tube current to the X-ray tube current adjusting means based on the calculation results of the two calculating means. And schedule execution means.

(E) Operation In the above configuration, when a power-off instruction signal is output from the on / off instruction means, in response to this, the power-down schedule calculation means causes the current tube detected by the tube voltage / tube current detection means to respond to the current signal. A power-down schedule is created in which the power is reduced linearly with time based on the values of the voltage and the tube current. The time schedule executing means outputs a control signal for reducing the tube voltage to the X-ray tube voltage adjusting means and a control signal for reducing the tube current to the X-ray tube current adjusting means based on the data of the power down schedule. I do. Thereby, the power applied to the X-ray tube is reduced linearly with time.

On the other hand, when the power-on instruction signal is output from the on / off instruction means, in response to this, the power-up schedule calculating means responds to the current tube voltage and tube current values detected by the tube voltage / tube current detection means. A power-up schedule for increasing the power linearly with time is created based on the power-up schedule. The time schedule executing means outputs a control signal for increasing the tube voltage to the X-ray tube voltage adjusting means and a control signal for increasing the tube current to the X-ray tube current adjusting means based on the data of the power-up schedule. I do. Thereby, the power applied to the X-ray tube is linearly increased with time.

(F) Embodiment FIG. 1 is a block diagram of an X-ray tube power supply device. In the figure, 1 is an X-ray tube power supply, 2 is an X-ray tube, 4 is an X-ray tube voltage adjusting means for increasing / decreasing a tube voltage applied to the X-ray tube 2, and 6 is applied to the X-ray tube 2 X-ray tube current adjusting means for increasing or decreasing the tube current to be applied.

Reference numeral 8 denotes a tube voltage / tube current detecting means for detecting a tube voltage and a tube current applied to the X-ray tube 2, and includes, for example, a voltmeter and an ammeter. Reference numeral 10 denotes on / off instructing means for instructing on / off of power (= tube voltage × tube current) applied to the X-ray tube 2, and is constituted by, for example, a keyboard.

Numeral 12 responds to the power-off instruction from the on / off instruction means 10 and linearly changes the power in time based on the values of the tube voltage and the tube current detected by the tube voltage / tube current detection means 8. A power-down schedule calculation means 14 for creating a power-down schedule to be lowered is provided with a tube voltage and tube current detected by the tube voltage / tube current detection means 8 in response to a power-on instruction from the on / off designation means 10. Is a power-up schedule calculating means for creating a power-up schedule for increasing the power linearly with time based on the value of the power-up schedule. A control signal 16 for increasing / decreasing the tube voltage is sent to the X-ray tube voltage adjusting means 4 and a control signal for increasing / decreasing the tube current is sent to the X-ray tube current adjusting means 16 based on the operation results of the two operation means 12, 14. 6 is a time schedule execution means for outputting the respective time schedules. Each of the arithmetic means 12 and 14 and the time schedule executing means 16 are constituted by, for example, a microcomputer.

Next, the power down and power up control operations of the X-ray tube 2 of the X-ray tube power supply device 1 having the above configuration will be described in the second.
This will be described with reference to the flowchart of FIG. 3 and FIG.

(I) Power Down Control Operation When a power down instruction signal (for example, a low level signal) is output from the on / off instruction means 10, the power down schedule calculation means 12 confirms this power down instruction (step S1). ), tube voltage, creating a power-down schedule reducing linearly to power based on the current value of the tube voltage V ₀ and the tube current I ₀ detected by the tube current detecting means 8 (step).

That is, the power down schedule calculation means 12
First, as shown in FIG.
The currently set power P ₀ (= V ₀ × I ₀ ) is determined from the values of the tube voltage V ₀ and the tube current I ₀ detected in step ( ₁ ). Also, a preset power reduction gradient k per unit time (for example, 10 w / se) is set so as not to cause a rapid thermal change to the X-ray tube 2.
c) and the above power P ₀ , the current power P ₀
Time Td required for the time to become zero and each time Tj (= j · Δ
T, j = 1, 2,... N, ΔT = Td / n) Power Pj
Are calculated based on the following equations.

_{Pj = P 0 -k · Tj (} 1) Td = P 0 / k (2) Subsequently, the power-down schedule calculation unit 12
From the values of the sustain voltages V ₁ and current tube voltage V ₀ of the filament of the X-ray tube 2 is set in advance so as not to cause discharge breakdown or the like, the tube voltage Jj and tube current after the time Tj elapsed Ij is calculated based on the following equations.

_{Vj = V 0 -Tj · (V} 0 -V 1) / Td (3) Ij = Pj / Vj (4) Thus, the tube voltage Vj for each time Tj, the value of the tube current Ij is calculated by the power-down schedule Is determined,
The data of the power down schedule is sent to the time schedule executing means 16 at the next stage.

Time schedule execution unit 16 determines whether or not the tube voltage Vj coincides with the stop voltage V ₁ (step), If they do not match, on the basis of the data of the power-down schedule, the course of the time Tj In each case, a control signal for lowering the tube voltage Vj is sent to the X-ray tube voltage adjusting means 4,
A control signal for reducing the tube current Ij is transmitted to the X-ray tube current adjusting means 6.
Respectively. Thereby, the power Pj (= Vj × Ij) applied to the X-ray tube 2 is reduced with a constant gradient k (step).

The predetermined time Td has elapsed, the tube voltage Vj becomes equal to the sustain voltage V ₁ (step), the tube current Ij at this point becomes zero, then the time schedule execution unit 16, X-rays tube voltage adjusting A control signal is output only to the means 4 and the tube voltage
Vj is a preset constant gradient 1 (for example, 5 kV / sec)
(Step). When the tube voltage Vj becomes zero (step), the control operation is stopped (step).

(Ii) Power-up control operation When a power-up instruction signal (for example, a high level signal) is output from the on / off instruction means 10, the power-up schedule calculation means 14 confirms the power-up instruction (step S1). ), the power-up schedule for power Pi increases linearly from the current increase permitted voltage V ₂ filament of the X-ray tube 2 is set in advance so as not to cause discharge breakdown or the like up to the target value V ₃ Create (step).

That is, the power-up schedule calculation means 12
First, as shown in FIG. 5, a target power P ₃ (= V ₃ × I ₃ ) is obtained from a target tube voltage V ₃ and a tube current I ₃ . Also,
A power increase gradient q per unit time set in advance so as not to give a rapid thermal change to the X-ray tube 2 (for example,
10w / sec) and from both the value of the target power P _3, and time Tu required to reach the power P ₃ of the target, the time Ti
(= I · ΔT, i = 1, 2,..., M, ΔT = Tu / m) and the power Pi after elapse are calculated based on the following equations.

Pi = q · Ti (5) Tu = P ₃ / q (6) Subsequently, the power down schedule calculation means 12
Calculates the tube voltage Vi and the tube current Ii after the lapse of each time Ti from the tube voltage current rise permission voltage V ₂ , the target value V _3, and the time Tu of the equation (6), respectively, based on the following equations.

Vi = V ₂ + Ti · (V ₃ −V ₂ ) / Tu (7) Ii = Pi / Vi (8) Thus, the values of the tube voltage Vi and the tube current Ii for each time Ti are calculated, and the power-up schedule is calculated. When determined, the power-up schedule data is sent to the time schedule execution means 16 at the next stage.

Leave time schedule execution unit 16 first determines whether or not the tube voltage Vi is coincident with the current increase permitting voltage V ₂ (step), if they do not match, keeping the tube current Ii to zero, the tube A constant gradient r that is set only for the voltage Vi
(For example, 5 kV / sec) (step). When the tube voltage Vi is equal to the current increase permitting voltage V ₂ (step), then, it is determined whether or not the tube voltage Vi is equal to the target value V ₃ (step), if they do not match,
Based on the data of the power-up schedule previously set, a control signal for increasing the tube voltage Vi is sent to the X-ray tube voltage adjusting means 4 and a control signal for increasing the tube current Ii every time Ti elapses. Are output to the X-ray tube current adjusting means 6, respectively. Thereby, the power Pi applied to the X-ray tube 2 is increased with a constant gradient q (step). Then, after a predetermined time period Tu, the tube voltage Vi matches the target value V _3,
That is, to achieve the target power P ₃ (step), to stop the control operation (step).

In the above embodiment, the time schedule of each time Tj, Ti is calculated in advance, but the current tube voltages Vj, Vi and the tube current Ij,
Enter the value of Ii, and sequentially, the tube voltage Vj ₁ , Vi ₁ , the tube current I
It is also possible to determine the control values of j ₁ and Ii ₁ .

(G) Effect According to the present invention, the setting operation of the tube voltage and the tube current applied to the X-ray tube is automated, so that the complicated setting operation is eliminated. Further, since the switching of the tube voltage and the tube current can be performed continuously, not stepwise, the shock of the discharge applied to the filament and the like can be reduced, and the life of the X-ray tube can be further improved as compared with the related art. The effect is exhibited.

[Brief description of the drawings]

1 is a block diagram of an X-ray tube power supply, FIG. 2 is a flowchart of a power-down control operation, FIG. 3 is a flowchart of a power-up control operation, FIG. FIG. 5 is an explanatory diagram of a procedure for creating a power-down schedule, and FIG. 5 is an explanatory diagram of a procedure for creating a power-up schedule. DESCRIPTION OF SYMBOLS 1 ... X-ray tube power supply device, 2 ... X-ray tube, 4 ... X-ray tube voltage adjusting means, 6 ... X-ray tube current adjusting means, 8 ... Tube voltage / tube current detecting means, 10 ... ... On / off instruction means, 12 ...
... power down schedule calculation means, 14 ... power up schedule calculation means, 16 ... time schedule execution means.

Claims (1)

(57) [Claims] An X-ray tube for increasing or decreasing a tube voltage applied to an X-ray tube.
An X-ray tube power supply device comprising: a tube voltage adjusting means; and an X-ray tube current adjusting means for increasing / decreasing a tube current applied to the X-ray tube, wherein the tube voltage applied to the X-ray tube and the tube Tube voltage / tube current detecting means for detecting current; on / off instructing means for instructing on / off of power (= tube voltage × tube current) applied to the X-ray tube; A power-down schedule in which the power is reduced linearly with time based on the values of the tube voltage and tube current detected by the tube voltage / tube current detection means in response to the power-off instruction of Schedule calculation means, and in response to a power-on instruction from the on / off instruction means, time-linearly changes power based on the values of the tube voltage and tube current detected by the tube voltage / tube current detection means. Increase A power-up schedule calculating means for creating a warm-up schedule; and a control signal for increasing / decreasing a tube voltage to the X-ray tube voltage adjusting means, and a control signal for increasing / decreasing a tube current based on the calculation results of the two calculating means. An X-ray tube power supply, comprising: a time schedule execution unit that outputs the X-ray tube current to each of the X-ray tube current adjustment units.