KR101215917B1 - Dual-purpose digital X-ray system with reduced low radiation dose and the radiographic application methods - Google Patents

Abstract

The present invention is to remove the scattering X-rays unnecessary for diagnosis as a digital medical image to reduce the exposure X-ray irradiation conditions to reduce the exposure dose of the patient, X-ray tube and a plurality of detectors of the X-ray The patient's half body can be taken at once as the patient is photographed while moving horizontally and vertically, and one detector acquires digital medical images and another detector reduces the x-ray exposure, which measures the patient's bone density. It relates to a digital X-ray photographing apparatus.
To this end, the present invention is to adjust the micro-gap (8 ~ 13mm) so that the high voltage generator 300 for X-ray imaging and the X-ray irradiated from the X-ray tube 30 can be adjusted to a thin fan beam (Fan Beam) A digital X-ray photographing apparatus 1, which is equipped with collimators 31 and 32, is provided. A multi-channel ionization detector is provided so that irradiated X-rays can be obtained through a subject and detect dual image data. The plurality of detectors 50 and 51 which are: MIC are horizontally disposed at a distance of approximately 1300 mm, and the X-ray tube 30 and the plurality of detectors 50 and 51 are simultaneously moved up and down, and the digital X-ray photographing apparatus ( 1) is characterized in that the bone density measuring unit 200 for measuring the bone density is formed.

Description

Dual-purpose digital X-ray system with reduced low radiation dose and the radiographic application methods

The present invention relates to a complex digital X-ray imaging apparatus having reduced X-ray exposure, and more particularly, to remove X-ray irradiation conditions by removing a grid for blocking scattering X-rays unnecessary for diagnosis as a digital medical image. It reduces the patient's exposure dose, and is equipped with X-ray tube and multiple detectors of the X-ray radiator so that the patient's half body can be taken at a time as the patient is taken horizontally and vertically and horizontally. The present invention relates to a complex digital X-ray imaging apparatus which reduces X-ray exposure, which acquires digital medical images and another detector measures a patient's bone density.

In general, a digital X-ray imaging apparatus is widely used as a medical device for photographing an internal structure of a subject such as a human body or an animal.

Conventional digital X-ray photographing apparatus uses X-rays passing through an indirect method to hit a photosensitive plate (scintillator) to produce visible light, and then through the CCD (Charge Coupled Devise) or TFT (Thin Film Transistor) with Photodiode Photographic equipment that converts signals and X-rays that pass through a direct-type subject are directly irradiated onto a TFT equipped with a photoconductor (or photoresistor) to obtain an image signal to obtain an image.

As shown in FIG. 1, the X-ray photographing apparatus is irradiated to a large area at a time in the form of a cone of X-rays radiated from an X-ray tube to bring scattering of X-rays and distortion of an image, and to reduce scattering of X-rays. There is a disadvantage that the software should be corrected in software to increase the irradiation dose and reduce the distortion of the acquired image by using.

In addition, the conventional digital X-ray imaging apparatus can acquire only a constant size image (up to 430 mm × 430 mm) by using a fixed detector (CCD or FPD) of a constant size (up to 430 mm × 430 mm), thereby diagnosing a half body of a patient. When shooting for 2 to 3 times the captured image by the software (Stiching) can acquire the image.

This is a problem that it is impossible to actually measure the actual skeleton length caused by the increase in the X-ray exposure of the patient and the increase of the imaging work time, the image of the joint by the number of times the patient is taken.

In addition, the BMD is a DEXA-type BMD that analyzes and measures bone density using dual energy absorption (DEXA: Dual Energy X-ray Abdorptiometry) as a separate device.

At present, the digital X-ray imaging apparatus and the BMD are each individually configured, each has a complicated structure, and is used separately according to each diagnostic function.

In other words, the above-mentioned conventional technology is used in the X-ray shielding space where the digital X-ray imaging apparatus and the bone density meter are used as separate equipments.

Therefore, in the past, digital X-ray imaging equipment and bone density measuring instruments are separately provided, so that busy modern people have to go through digital X-ray imaging equipment to diagnose bones and bone density measuring instruments to measure bone density. Increasing the amount of X-ray exposure of the patient, and taking a lot of time for the diagnosis along with the problem that the imaging cost is excessive.

Therefore, the present invention has been made to solve the above problems, the object of the first is to form a plurality of detectors X-rays generated by the X-ray generator is obtained through the subject, so that one detector is X-ray photographed image Another detector is a multipurpose digital X-ray imaging device that can measure bone density.

Second, by removing the grid (grid) to prevent scattering during X-ray imaging can reduce the exposure of the patient by reducing the dose of X-rays.

Third, the X-ray tube and the detector are taken while moving vertically and horizontally to reduce the distortion of the image, thereby reducing the correction of the image distortion in the software, thereby maximizing the accuracy of the diagnosis.

Fourth, it is possible to minimize the radiation exposure of the patient as well as to shorten the shooting time by allowing the body or the whole body to be photographed at one time by one operation.

Fifth, since the photographing sites are photographed to be connected to each other without disconnection in one shot, the accuracy of diagnosis and photographing can be maximized, thereby increasing the accuracy of diagnosis by the examiner as well as the patient.

Sixth, the present invention provides a composite digital X-ray photographing apparatus with reduced X-ray exposure, which enables to simultaneously photograph digital X-ray imaging and bone density measurement by combining a single device.

In order to achieve the above object, the present invention is capable of adjusting a very small gap (8 to 13 mm) so that a high voltage generator for X-ray imaging and an X-ray radiated from an X-ray tube can be controlled by a thin fan beam. A digital X-ray photographing apparatus equipped with a collimator is provided, and a plurality of detectors, which are multi-channel ionization chambers (MICs), are arranged so that irradiated X-rays can be acquired through a subject and detect double image data. Placed at a distance of 1300 mm, allowing the X-ray tube and the plurality of detectors to move up and down simultaneously, and a bone density measuring unit for measuring bone density on the digital X-ray camera, wherein the X-ray tube has reduced X-ray exposure. In providing a photographing apparatus.

As described above, the present invention is equipped with a plurality of detectors in one digital X-ray imager, and can measure the iliac X-ray image and bone density by one X-ray, reducing the number of X-rays of the patient, and By removing the grid to block the scattering (line) to reduce the radiation dose to take the effect of reducing the exposure of the patient.

In addition, the present invention can be obtained by moving the scanning range of the shooting range to obtain the image of the long bone without breaking, and to obtain the image of the actual length is not distorted to increase the accuracy of the diagnosis ultimately to protect the X-ray exposure of the patient, Accurate diagnosis, cost reduction of equipment, and shortening of shooting time can reduce the diagnosis cost of lesion.

1 is a photographing example of a conventional X-ray photographing apparatus.
2 is an exemplary view showing the overall configuration of a composite digital X-ray imaging apparatus according to the present invention.
Figure 3 is a schematic flow diagram of a composite digital X-ray imaging apparatus according to the present invention.
Figure 4 is a planar view showing a digital X-ray photographing apparatus capable of half body imaging in accordance with the present invention.
5 is a front view showing a digital X-ray photographing apparatus capable of photographing a human body according to the present invention.
6 is a front view showing a digital X-ray photographing apparatus capable of taking a human body in accordance with the present invention.
7 is a side view showing a digital X-ray photographing apparatus capable of taking a human body in accordance with the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is an exemplary view showing the overall configuration of a composite digital X-ray imaging apparatus according to the present invention, Figure 3 shows a schematic flow diagram of a composite digital X-ray imaging apparatus according to the present invention, Figure 4 Fig. 5 is a planar view showing a digital X-ray photographing apparatus capable of photographing a human body according to the present invention. FIG. 5 is a front view showing a digital X-ray photographing apparatus capable of photographing a human body according to the present invention. Front view showing a digital X-ray photographing apparatus capable of taking a human body in accordance with the present invention, FIG. 7 is a side view showing a digital X-ray photographing apparatus capable of taking a whole human body according to the present invention.

As shown in Figures 2 to 5, the present invention is a composite digital X-ray imaging apparatus for diagnosing lesions by photographing the inside of the patient's body using digital X-rays, the composite digital X-ray imaging apparatus is Generated by the digital X-ray photographing apparatus 1, the high voltage generator 300 capable of generating X-rays in the digital X-ray photographing apparatus 1, and the digital X-ray photographing apparatus 1 It is configured to include an X-ray control device 400 to control the X-rays to be.

The digital X-ray photographing apparatus 1 is connected to the base plate 10 formed on the bottom surface, the camera main body 20 formed on the base plate 10, and the camera main body 20. X-ray tube 30 to be guided downward, the detector arm 40 is connected to the camera main body 20, and the X-ray tube irradiated from the X-ray tube port 30 to the detector arm 40 A plurality of detectors 50, 51 for scanning and inputting are mounted.

The camera main body 20 has an instrument stand 21 formed therein, and an operating means for guiding the detector arm 40 and the X-ray tube 30 up and down on the instrument stand 21. 22) is formed.

The driving means 22 is a drive motor 221 is formed on the instrument stand 21, the guide rail 222 to move the detector arm 40 on the upper and lower ends of the instrument stand 21 Is formed, is connected to the drive motor 221 to the guide rail 222 is rotated by the drive of the drive motor 221, the detector arm 40, the X-ray tube 30 and the detector (50, 51) bottom A belt 223 is formed to move up, down or left and right to be horizontal with the surface.

The X-ray tube 30 is formed with a plurality of first and second fan beam collimators (31, 32) that can be adjusted to a thin X-ray beam radiated from the X-ray tube port 30 for scanning imaging Lose.

The detectors 50 and 51 are formed in a plurality of upper and lower portions of the detector arm 40, and a filter 60 is formed in one detector 51 to measure the bone density by reducing the X-ray dose. Lose.

As described above, the one detector 50 scans the X-rays irradiated from the X-ray tube port 30 to perform digital X-ray imaging, and the other detector 51 irradiates the X-ray tube port 30. Scan the X-rays to measure bone density.

In addition, the detectors 50 and 51 may be formed of a multichannel ionization chamber (MIC).

Meanwhile, in another example of the digital X-ray imaging apparatus 1 according to the present invention, as shown in FIGS. 6 and 7, the X-ray tube 30 having the first and second fan beam collimators 31 and 32 is formed. The C arm driver 70 is formed on the base plate 10, and is connected to the C arm driver 70 by a guide rail 222 along the guide rail 222 by driving the C arm driver 70. The C arm 90 to be guided is formed.

In addition, a plurality of detectors 50 and 51 are formed at the lower end of the table T to input data to scan X-rays irradiated from the X-ray tube 30 and to measure an X-ray photographed image and bone density. .

In the photographing method to shoot the inside of the body using the composite digital X-ray imaging apparatus according to the present invention,

First, when the X-ray control device 400 is operated, the high pressure generated by the high voltage generator 300 is generated by the operation means 22 of the digital X-ray photographing apparatus 1 of the half body or the digital X-ray imaging apparatus 1 of the whole body. X-rays are generated through the X-ray tube port 30 is moved to the upper, lower, left, right according to the operation,

The X-rays generated from the X-ray tube port 30 are irradiated through a secondary fan beam collimator 32 that can be adjusted to a fan beam through the primary fan beam collimator 31 provided in the X-ray tube port 30. Become,

The X-rays irradiated through the first and second fan beam collimators 31 and 32 are input to the plurality of detectors 50 and 51 to scan the half body or the whole body of the patient to measure the X-ray imaging and bone density.

The captured image data input to the detectors 50 and 51 may be processed by the image signal processing apparatus and transferred to the digital X-ray image processing unit 100 and the bone density measuring unit 200.

In addition, the plurality of detectors 50 and 51 according to the operation of the operating means 22 so that the X-ray tube 30 can minimize the distortion of the image and the distortion of the image with one shot of the half body or the whole body of the patient. At the same time, it moves horizontally up, down, left and right.

Looking at the operation state of the composite digital X-ray imaging apparatus according to the present invention as described above.

First, X-rays generated from the X-ray tube sphere 30 at high pressure generated by the high voltage generator 300 are irradiated through the first and second fan beam collimators 31 and 32, and the first and second fan beam collimators. X-rays irradiated through the (31, 32) is scanned by scanning the body of the patient is input to the detector (50, 51).

When the inspector image data is input to the detectors 50 and 51, the data input to one detector 50 is transferred to the digital X-ray image processing unit 100 to obtain an X-ray image. The data input to the other detector 51 is transferred to the bone density measuring unit 200 to measure the bone density of the tester.

As such, the X-rays generated through the X-ray tube 30 are input to the detectors 50 and 51 so as to measure the X-ray image and bone density while scanning the body of the examiner. 51) the data input from the digital X-ray image processing unit 100 and the bone density measuring unit 200 is transmitted to one digital X-ray imager 1 so that the X-ray imaging of the examiner and bone density can be simultaneously examined do.

In addition, the composite X-ray imaging apparatus according to the present invention is the X-ray tube 30 and the detector 50, 51 while the detector arm 40 is guided up and down according to the operation of the operating means 22. Is moved up and down horizontally with the bottom surface, thereby reducing the distortion and correction of the inspected image.

In addition, the upper and lower horizontal movement of the X-ray tube 30 can scan the whole body of the examiner as well as the whole body to scan a wide image in one operation to minimize the radiation exposure of the patient do.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

1: digital x-ray camera 10: base plate
20: camera body 21: instrument stand
22: operating means 30: X-ray tube
31: 1st Fan Beam Collimator 32: 2nd Fan Beam Collimator
40: detector arm 50, 51: detector
60 filter 70 C arm drive unit
90: C-arm 100: Digital X-ray image processing unit
200: bone density measuring unit 221: driving motor
222 guide rail 223 belt
300: high voltage generator 400: X-ray control device
T: table

Claims (8)

A base plate formed on the bottom surface;
A camera body formed on the base plate;
An X-ray tube connected to the main body of the camera and guided up and down horizontally with the bottom surface;
A detector arm connected to the camera body;
X-ray irradiated from the X-ray tube to the detector arm is composed of a plurality of detectors for inputting data to scan the subject X-ray image and bone density,
The camera body, the instrument stand is formed therein,
An operating means is formed on the instrument stand to guide the detector arm, the X-ray tube, and the detector up and down horizontally with the bottom surface to minimize distortion of the captured image and correction of the image distortion.
The driving means is a drive motor is formed on the instrument stand, a guide rail is formed to move the detector arm on the upper and lower ends of the instrument stand, is connected to the drive motor to the guide rail is rotated by the drive of the drive motor A belt is provided to move the detector arm, the X-ray tube, and the detector up, down, left, or right horizontally with the bottom surface.
The rear of the X-ray tube sphere further includes a plurality of first and second fan beam collimators that can be adjusted by a thin Fan X-ray beam radiated from the X-ray tube sphere for scanning imaging,
The detector is formed in a plurality of upper and lower portions of the detector arm, one detector is provided with a filter to measure the bone density by reducing the X-ray dose,
The C-arm driver formed on the base plate and the C-arm connected to the C-arm driver by a guide rail and guided along the guide rail by the drive of the C-arm driver are additionally provided. Reduced composite digital X-ray imaging device. delete delete delete The method of claim 1,
The detector is a composite digital X-ray imaging apparatus with reduced X-ray exposure, characterized in that formed by a multi-channel ionization chamber (MIC). delete delete delete

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