JP3163995B2 - X-ray high voltage equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an X-ray high-voltage device attached to an X-ray fluoroscope or the like, and more particularly, to a device having a mechanism for increasing a fluoroscopic tube current in accordance with a fluoroscopic tube voltage during fluoroscopy. The present invention relates to an X-ray high-voltage device having a mechanism for setting a preheating value of a filament heating current during fluoroscopy by a set value of fluoroscopic tube current.

[0002]

2. Description of the Related Art A conventional X-ray high voltage apparatus of this type is shown in FIG.
It is configured as shown in FIG. At the time of fluoroscopy, when the fluoroscopic tube voltage (FKV) is set from the fluoroscopic tube voltage setting circuit 1, the fluoroscopic tube current (FmA) is changed by the fluoroscopic tube current setting circuit 2 according to the relationship shown in FIG. ). When the minimum fluoroscopic tube current (FmA _min ) is supplied from the fluoroscopic tube current setting circuit 2 to the gain adjuster 7, the offset adjustment circuit 4 sets “0 m
A ". The base current adjuster 5 is adjusted so as to be, for example, the minimum value (base value: FFH _min ) of the filament heating current shown in FIG. Further, when the maximum fluoroscopic tube current (FmA _max ) is supplied from the fluoroscopic tube current setting circuit 2 to the gain adjuster 7, the gain adjuster 7 sets the maximum value (FFH _max ) of the filament heating current from the adder 6. It has been adjusted to output. Thus, the preheating value of the filament heating current is set according to the set value of the fluoroscopic tube current, and is output from the adder 6. Note that reference numeral 10 in FIG. 3 denotes an adder that constitutes a feedback circuit, 11 denotes a filament heating circuit, 12 denotes a high voltage generator, and 13 denotes an X-ray tube.

According to the configuration of this conventional apparatus, for example, in FIG. 4 and FIG. 5, when FKV1 is set as the fluoroscopic tube voltage, FmA1 is set as the fluoroscopic tube current accordingly, and the fluoroscopic tube current is set. With respect to the value FmA1, the preheating value of the filament heating current during fluoroscopy is FFH1
Is set.

That is, as shown in FIGS. 4 and 5, the preheating value of the filament heating current at the time of fluoroscopy is the minimum fluoroscopic tube current value (FmA _min ) corresponding to the minimum fluoroscopic tube voltage value (FKV _min ). The minimum filament heating current value (FFH _min ) and the maximum fluoroscopic tube voltage value (FKV _max )
The maximum filament heating current value (FFH _max ) with respect to the maximum fluoroscopic tube current value (FmA _max ) corresponding to the above is obtained by linear interpolation.

[0005]

However, the prior art having such a structure has the following problems. Since the emission characteristics of the filament of the X-ray tube have a logarithmic relationship with the heating value of the filament, the preheating value of the filament heating current at the time of fluoroscopy is set by linear interpolation as in the above-described conventional apparatus. The minimum and maximum filament heating current (FFH _min
And FFH _max ), the preheating of the filament can be accurately performed only at two points, and the preheating of the filament cannot be performed accurately with the filament heating current value (for example, FFH1) between them. So, in most cases,
There is a problem that it is impossible to output an appropriate fluoroscopic tube current equal to the set value simultaneously with the output of the fluoroscopic X-ray.

[0006] This type of X-ray high-voltage device is usually provided with a feedback circuit including an adder 10, a tube current detection circuit 14, a feedback control circuit 15, and the like. It takes time for the fluoroscopic tube current to stabilize, and until then the fluoroscopic tube current hunts largely (changes to a large or small value with an appropriate fluoroscopic tube current in between).

In addition, when X-ray fluoroscopy is performed by incorporating the fluoroscopic brightness automatic adjustment circuit 20, there are the following inconveniences. Here, the fluoroscopic brightness automatic adjustment circuit 20 displays the X-rays emitted from the X-ray tube 13 through the subject M, and the fluoroscopic images captured by the image intensifier 21 and the television camera 22 on the monitor 23. When the brightness is bright, the set value of the fluoroscope voltage is automatically reduced, and when the brightness is dark, the set value of the fluoroscope voltage is automatically increased. , A circuit for automatically adjusting the fluoroscopic tube voltage according to the display luminance of the current fluoroscopic image.

If an appropriate preheating value is not set as in the above-described conventional apparatus, the fluoroscopic tube current is not immediately stabilized, and the fluoroscopic brightness automatic adjustment circuit 20 operates to change the set value of the fluoroscopic tube voltage. In some cases, the fluoroscopy tube voltage fluctuated until the fluoroscopy tube current stabilized at an appropriate value. In particular, when the value of the maximum fluoroscopic tube current value (FmA _max ) (maximum filament heating current value (FFH _max )) is large, the difference between the pre-heating value set by linear interpolation and the appropriate pre-heating value is calculated. Since the difference became large, the fluctuation of the fluoroscopic tube voltage by the fluoroscopic brightness automatic adjustment circuit 20 was conspicuous.

The present invention has been made in view of the above circumstances, and an X-ray high-voltage apparatus capable of setting an appropriate preheating value of a filament heating current with respect to a set value of a fluoroscopic tube current. The purpose is to provide.

[0010]

The present invention has the following configuration to achieve the above object. That is, the present invention has a mechanism for raising the fluoroscopic tube current in accordance with the fluoroscopic tube voltage at the time of fluoroscopy, and having a mechanism for setting the preheating value of the filament heating current at fluoroscopic time by the set value of the fluoroscopic tube current. In the line high voltage device, the base value of the filament heating current is added to an addition value proportional to the logarithmic value of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current, and the filament heating current at the time of fluoroscopy is added. The present invention is characterized in that a preheating value is set.

[0011]

According to the present invention, an additional value proportional to the logarithmic value of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current is added to the base value of the filament heating current, and the filament at the time of fluoroscopy is added. Since the configuration is such that the preheating value of the heating current is set, the emission value of the filament of the X-ray tube having a logarithmic function relationship with the heating value of the filament is set for the set value of the fluoroscopic tube current. An appropriate preheating value for the filament heating current can be set.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram showing a configuration of an X-ray high-voltage device according to one embodiment of the present invention.
FIG. 4 is a graph showing a preheating value of a filament heating current set by the apparatus of this embodiment with respect to a set value of a fluoroscopic tube current.

A fluoroscopic tube voltage setting circuit 1 is a circuit for setting a fluoroscopic tube voltage during fluoroscopy. The fluoroscopic tube voltage (FKV) set by the fluoroscopic tube voltage setting circuit 1 is input to a fluoroscopic tube current setting circuit 2. You. In the fluoroscopic tube current setting circuit 2, for example, the fluoroscopic tube current (FmA) corresponding to the fluoroscopic tube voltage is set to be increased in a relationship as shown in FIG.

An offset adjusting circuit 4 constituted by a variable resistor or the like is connected to a logarithmic conversion circuit 3 when the set value of the fluoroscopic tube current from the fluoroscopic tube current setting circuit 2 is a minimum value (base value: FmA _min ). Is adjusted so that the composite value of the input of “1” becomes “0 mA”. That is, the logarithmic conversion circuit 3 includes an increment (FmA _set −Fm) of a set value (FmA _set ) of the fluoroscopic tube current with respect to the base value (FmA _min ) of the fluoroscopic tube current.
A _min ).

In the logarithmic conversion circuit 3, the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current is logarithmically converted, and the logarithmic value of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current is calculated. Is output.

[0016] Base current control composed of a variable resistor or the like
The integrator 5 has the minimum tube current (FmA) shown in FIG._min)
Filament heating current value (base value: F
FH _min), And enters the adder 6.
Is forced.

The gain adjuster 7 composed of a variable resistor or the like outputs the output from the adder 6 when the maximum fluoroscopic tube current set value (FmA _max ) is input to the logarithmic conversion circuit 3. The maximum filament heating current (FFH) shown in FIG.
_max ) has been adjusted to be. The adder 6 outputs a value obtained by adding the filament heating current base value from the base current adjusting path 5 and the added value output from the logarithmic conversion circuit 3 and adjusted by the gain adjuster 7.

That is, the logarithmic value of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current output from the logarithmic conversion circuit 3 is the maximum value of the filament heating current base value (FFH _min ) by the gain controller 7. The value is adjusted in proportion to the range between the values (FFH _max ), and the adjusted value is added to the base value of the filament heating current by the adder 6 as an added value.

As a result, the preheating value of the filament heating current output from the adder 6 is set logarithmically with respect to the fluoroscopic tube current as shown by the solid line in FIG. It is possible to set an appropriate preheating value of the filament heating current in accordance with the emission characteristic of the filament of the X-ray tube having a logarithmic relationship with the heating value of the filament. In addition,
For reference, the preheating value of the filament heating current set by the conventional apparatus and the dotted line are shown.

The other components are the same as those of the conventional device, and therefore, are denoted by the same reference numerals as in FIG. Note that the filament heating circuit 11 is a circuit that supplies an AC power, which is an input filament heating current, to the high-voltage generator 12. The feedback control circuit 15 compares the tube voltage detected by the tube voltage detection circuit 14 with the set fluoroscopic tube voltage, and adjusts an adjustment value (± ΔFFH) corresponding to a difference between the set value and the feedback signal. It is configured to output as.

According to the above embodiment, an appropriate value is set as the preheating value of the filament heating current in accordance with the set value of the fluoroscopic tube current, and the filament is preheated with the optimum preheating current. As soon as the line is output, an appropriate fluoroscopic tube current equal to the set value can be output.

Further, even if the preheating value of the filament heating current set in the above embodiment deviates from the ideal value, the deviation is very small as compared with linear interpolation as in the conventional apparatus. Therefore, even if the adjustment by the feedback circuit is performed, it does not take much time for the fluoroscopic tube current to stabilize, and the fluoroscopic current does not largely hunt.

Further, even in the case where X-ray fluoroscopy is performed by incorporating the fluoroscopic brightness automatic adjustment circuit 20, an appropriate preheating value is set in the above embodiment, so that the fluoroscopic tube current is immediately stabilized, and the fluoroscopic tube is stabilized. The voltage does not fluctuate significantly. Of course, even when the value of the maximum fluoroscopic tube current value (FmA _max ) (maximum filament heating current value (FFH _max )) is large, the fluoroscopic tube voltage does not fluctuate similarly.

In the above-mentioned embodiment, the logarithmic conversion of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic current is performed by the logarithmic converter circuit 3. However, the logarithmic conversion is performed by a circuit using an operational amplifier or the like. May be approximated.

[0025]

As is apparent from the above description, according to the present invention, the base value of the filament heating current is proportional to the logarithmic value of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current. Since the preheating value of the filament heating current at the time of fluoroscopy is set by adding the addition value, it is necessary to set an appropriate preheating value of the filament heating current with respect to the set value of the fluoroscopic tube current. Can be.
Therefore, immediately after outputting the fluoroscopic X-ray, an appropriate fluoroscopic tube current equal to the set value can be output, and the fluoroscopic tube current does not hunt largely as in the conventional apparatus. Also, when X-ray fluoroscopy is performed by incorporating a fluoroscopic automatic adjustment circuit, an appropriate filament heating current is set as a pre-heating value. There is no large fluctuation of the tube voltage.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a configuration of an X-ray high-voltage device according to one embodiment of the present invention.

FIG. 2 is a graph showing a preheating value of a filament heating current set by the apparatus according to the present embodiment with respect to a set value of a fluoroscopic tube current.

FIG. 3 is a circuit diagram showing a configuration of a conventional device.

FIG. 4 is a graph showing an example of a fluoroscopic tube current set with respect to a fluoroscopic tube voltage.

FIG. 5 is a diagram showing a graph of a preheating value of a filament heating current set by a conventional device with respect to a set value of a fluoroscopic tube current.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 fluoroscopic tube voltage setting circuit 2 fluoroscopic tube current setting circuit 3 logarithmic conversion circuit 4 offset adjustment circuit 5 base current regulator 6 adder 7 gain regulator

Claims (1)

(57) [Claims] An X-ray having a mechanism for increasing a fluoroscopic tube current in accordance with a fluoroscopic tube voltage during fluoroscopy, and a mechanism for setting a preheating value of a filament heating current at fluoroscopic time according to a set value of the fluoroscopic tube current. In the high-voltage device, an addition value proportional to the logarithmic value of the increment of the set value of the fluoroscopic tube current with respect to the base value of the fluoroscopic tube current is added to the base value of the filament heating current, and the filament heating current at the time of fluoroscopy is calculated in advance. An X-ray high-voltage device characterized in that a heating value is set.