KR101229327B1 - Dual ceiling Ｘ―ray system - Google Patents

Abstract

Dual sealing x-ray system according to the present invention, the rail unit configured in the ceiling; An irradiation unit installed below the rail unit and irradiating X-rays; And a detection unit installed below the rail unit and absorbing the irradiated X-rays.
In the present invention, the horizontal position can be adjusted by the first moving member and the second moving member which are moved in the rail, and the first telescopic member and the second telescopic member are respectively provided on the two first and second moving members. By being comprised, height adjustment can be made freely up and down.
In addition, as the first bracket is installed to be rotated on the first telescopic member, the irradiator may be horizontally rotated. In addition, the irradiator and the detector may be vertically rotated by the first and second driving members to match the center points with respect to each other.
Accordingly, the present invention can easily and easily take an X-ray photographed at any position.

Description

Dual ceiling X-ray system

The present invention relates to a dual sealing x-ray system, which can be easily and easily X-ray imaging of the subject at any position.

In general, when the high-speed electrons collide with an object, electromagnetic waves with strong penetrating power are emitted, and the emitted electromagnetic waves are called X-rays.

The discovery of X-rays with strong penetrating power makes it possible to observe the internal state of humans from the outside, thus making a significant contribution to the development of the medical field.

That is, since the state of organs or bones inside the human cannot be grasped from the outside, when an abnormal symptom occurs in the body, the inside of the human body was opened and the naked eye was judged for abnormalities.

The discovery of X-rays by Roentgen and its application to the medical industry made it possible to determine the presence of abnormalities in the body by X-ray imaging from the outside of humans, which was performed before X-ray discovery. .

However, the conventional X-ray imaging apparatus used for medical use has been inconvenient disadvantages and limitations in various photographing such as photographing angles in photographing a subject, and thus, there is a need for improving the X-ray imaging apparatus.

The present invention has been made to solve the above problems, and an object thereof is to provide a dual sealing X-ray system that can be easily and easily X-ray imaging at any position.

In order to achieve the above object, a dual sealing X-ray system according to a preferred embodiment of the present invention includes: a rail unit configured in a ceiling; An irradiation unit installed below the rail unit and irradiating X-rays; And a detection unit installed below the rail unit and absorbing the irradiated X-rays.

At this time, the rail unit, a rail member installed on the ceiling; And two moving members moving along the rail member.

Specifically, the rail member, a rail frame disposed in one direction; a guide rod disposed along the longitudinal direction of the rail frame; And a rack gear disposed on the rail frame in parallel with the guide rod.

The first and second moving members may each include a main body that slides along the guide rod; A moving motor mounted to the main body; A moving reducer connected to the moving motor; And a pinion gear configured at an end of a rotation shaft of the movement reducer and engaged with the rack gear to rotate along the rack gear.

The irradiation unit may include: a first telescopic member installed on the moving member and configured to extend and contract downward; And an irradiator configured to radiate the X-rays at a lower end of the first telescopic member.

The first telescopic member may include: a cylindrical first telescopic bar having a structure in which the first telescopic member is fixed to the movable member and having a structure in which a plurality of unit bars overlap each other; A first winding drum which is stretched downward through the inside of the first telescopic bar and winds or unwinds a cable connected to the unit bar at the bottom; A first winding motor for providing a rotational force of the first winding drum; A first winding reducer fixed to the moving member and mounted with the first winding motor; And a first winding gear box which connects the first winding reducer to the first winding drum and is configured to transmit the rotational force of the first winding motor to the first winding drum.

In addition, the irradiation unit, the first bracket is installed so as to transverse to the lower end of the first telescopic member; And a first driving member fixed to the first bracket and configured to vertically rotate the irradiator mounted on one side thereof.

At this time, the first driving member, a first longitudinal motor for providing a longitudinal power to the irradiator; A first reducer fixed to the first bracket and mounted with the first longitudinal rotation motor; And a first gear box connecting the first decelerator and the irradiator and configured to transmit the longitudinal power of the first longitudinal rotation motor to the irradiator.

The detection unit may include: a second telescopic member installed on the moving member and configured to extend and contract downward; And a detector which is configured at a lower end of the second telescopic member and absorbs the irradiated X-ray.

The second telescopic member may include: a cylindrical second telescopic bar having a structure in which the second telescopic member is disposed downwardly and fixed to the moving member and having a structure in which a plurality of unit bars overlap each other; A second winding drum which is wound downward through the inside of the second telescopic bar to wind or unwind a cable connected to the unit bar at a lower end of the second telescopic bar; A second winding motor for providing a rotational force of the second winding drum; A second winding reducer fixed to the moving member and mounted with the second winding motor; And a second winding gear box which connects the second winding reducer to the second winding drum and is configured to transmit the rotational force of the second winding motor to the second winding drum.

In addition, the detection unit, a second bracket fixed to the lower end of the second telescopic member; And a second driving member fixed to the second bracket and configured to vertically rotate the detector mounted at one side.

At this time, the second drive member, a second longitudinal rotation motor for providing a longitudinal power to the irradiator; A second reducer fixed to the second bracket and mounted with the second longitudinal rotation motor; And a second gear box connecting the second reducer to the irradiator and configured to transfer the longitudinal power of the second longitudinal motor to the detector.

As an example, the irradiator may include: a first telescopic member installed on the first moving member and configured to extend and contract downward; An irradiator configured to be disposed at a lower end of the first telescopic member to irradiate the x-rays; A first bracket installed to transversely rotate at a lower end of the first telescopic member; And a first driving member fixed to the first bracket and configured to vertically rotate the irradiator mounted on one side, wherein the detection unit is installed on the second moving member and configured to extend and contract downward. A second telescopic member; A detector configured to be disposed at a lower end of the second telescopic member to absorb the irradiated X-rays; A second bracket fixed to the lower end of the second telescopic member; And a second driving member fixed to the second bracket and configured to vertically rotate the detector mounted on one side, wherein the first moving member or the second moving member is moved so that the irradiator and the detector are in a straight line. The first bracket may be extended toward the second telescopic member, or the second bracket may be extended toward the first telescopic member, so that the first bracket may be disposed on the second telescopic member.

Furthermore, the first driving member is bent to one side with respect to the extended first bracket, or the second driving member is bent to one side with respect to the extended second bracket. Can be.

In the dual sealing X-ray system according to the present invention, since the rail unit is formed on the ceiling, as the first telescopic member and the second telescopic member are moved downwardly from the ceiling, the space can be effectively used. There is no mobile constraint.

In addition, it is possible to adjust the horizontal position by the first moving member and the second moving member moved in the rail, the first telescopic member and the second telescopic member is formed in the two first and second moving members, respectively, The height can be adjusted freely up and down.

In addition, as the first bracket is installed to be rotated on the first telescopic member, the irradiator may be horizontally rotated. In addition, the irradiator and the detector may be vertically rotated by the first and second driving members to match the center points with respect to each other.

Furthermore, as the irradiator or detector is positioned at a point spaced apart from the first telescopic member and the second telescopic member toward each other, the irradiator and the detector are arranged in a straight line, so that the irradiator and the detector are placed on the upper and lower sides of the subject lying on the bed. By being able to arrange | position each, even if there is one rail member, an X-ray image of a subject can be smoothly taken.

Accordingly, the present invention has the effect that it is easy and easy to take the X-ray photographed at any position.

1 to 3 is a perspective view showing a dual sealing x-ray system according to a preferred embodiment of the present invention.
4 is an enlarged view illustrating an internal structure of a rail unit in the dual sealing x-ray system of FIG. 1.
FIG. 5 is an exploded view illustrating first and second telescopic members in the dual sealing x-ray system of FIG. 1.
FIG. 6 is an exploded view illustrating an irradiation unit in the dual sealing x-ray system of FIG. 1.
7 is an exploded view illustrating a detector in the dual sealing x-ray system of FIG. 1.

1 to 3 are perspective views showing a sealing type x-ray apparatus according to a preferred embodiment of the present invention, Figure 4 is an enlarged view of the internal structure of the rail unit in the dual sealing x-ray system of FIG.

5 is an exploded view showing the first and second telescopic members in the dual sealing x-ray system of FIG. 1, and FIG. 6 is an exploded view showing the irradiator in the dual sealing x-ray system of FIG. 1, and FIG. 7 is the dual sealing of FIG. 1. An exploded view of a detector in an X-ray system.

Referring to the drawings, the present invention includes a rail unit 100 that is configured on the ceiling, and the irradiation unit 200 and the detection unit 300 is installed below the rail unit 100.

The rail unit 100 is installed on the ceiling, preferably may be disposed to be parallel to the floor in the transverse direction.

As the rail unit 100 is configured in the ceiling as described above, the first telescopic member 220 and the second telescopic member 320 are moved downwardly from the ceiling, so that the space can be efficiently used, so that the subject lies down. There is an advantage that there is no constraint on the movement of the bed.

The rail unit 100 includes a straight rail member 120 and a first moving member 130 and a second moving member 140 configured to move to the rail member 120.

Specifically, as illustrated in FIG. 4, the rail member 120 includes a rail frame 122 disposed in one direction, a guide rod 124 and a rack gear 126 mounted to the rail frame 122. Equipped.

At this time, the rail frame 122 is preferably disposed so that the two ends are mutually spaced apart in parallel to each other so that the moving member 130, 140 to be described later is safely moved.

In addition, the guide rod 124 is mounted in the longitudinal direction from the inside of the rail frame 122.

In addition, the rack gear 126 is installed on the rail frame 122 in parallel with the guide rod 124.

At least one rail member 120 configured as described above may be installed on the ceiling. As an example, two rail members 120 may be adjacent to each other and arranged in parallel, wherein the first moving member 130 and the second moving member 140 may be installed on different rail members, respectively. Of course.

At this time, the first moving member 130 and the second moving member 140 has the same configuration, and with reference to FIG. 4 with reference to the second moving member 140 in detail, the second moving member 140 The main body 142 includes a moving motor 144 mounted on the main body 142, a moving reduction gear 146, and a pinion gear 148.

The main body 142 is configured to slide along the guide rod 124, the portion seated on the guide rod 124 is wrapped around the guide rod 124 is moved without deviating from the path of the guide rod 124.

Here, the pinion gear 148 is configured at the end of the rotary shaft of the movement reducer 146 and is engaged with the rack gear 126 of the rail member 120 to move along the rack gear 126. Of course, the rotational force at this time is provided by the moving motor 144, and is the rotational force of the large force decelerated through the movement reducer 146.

The rail unit 100 configured as described above is provided with an irradiation unit 200 and a detection unit 300 arranged in a downward direction, respectively.

The irradiator 200 is installed on the rail unit 100 and configured to irradiate X-rays, and includes a first telescopic member 220 and an irradiator 280.

Here, the first telescopic member 220 is configured to extend and contract downward on the movable member 130.

In detail, the first telescopic member 220 includes a first telescopic bar 222 disposed below and fixed to the moving member 130, a first winding drum 224 provided on an upper portion of the first telescopic bar 222, and A first winding motor 226 for rotating the first winding drum 224, a first winding reducer 228 for slowing the rotation of the first winding motor 226, and the first winding reducer 228 and the first winding motor 226. A first winding gear box 229 connecting the first winding drum 224 is provided.

The first telescopic bar 222 is fixed to the mobile member 130 to be disposed downward, has a structure in which a plurality of unit bars overlap each other, and takes a tubular shape.

Accordingly, the first telescopic bar 222 extends downwardly by pulling the lower unit bars downward from the unit bars overlapping each other.

In addition, by raising the unit bar to the upper side so that the unit bars overlap each other again to achieve a contracted structure.

The first winding drum 224 extends downward through the inside of the first telescopic bar 222 and is configured to wind or unwind the first cable 224a connected to the lower unit bar.

At this time, the first winding motor 226 provides a rotational force of the first winding drum 224. In addition, the first winding reducer 228 connected to the first winding drum 224 slows down the rotational speed of the first winding motor 226.

In addition, the first winding gear box 229 connects the first winding reducer 228 and the first winding drum 224 to transmit the rotational force of the first winding motor 226 to the first winding drum 224. It is composed.

In addition, the irradiator 200 may further include a first bracket 240 configured at the lower end of the first telescopic member 220 and a first driving member 260 fixed to the first bracket 240. have.

At this time, the first bracket 240 is installed to be transversely rotated to the lower end of the first telescopic member 220. Accordingly, as shown in FIG. 1, the first bracket 240 may be rotated about a portion connected in the lateral direction.

In addition, the first driving member 260 is fixed to the first bracket 240, and is configured to longitudinally rotate the irradiator 280 mounted on one side.

In detail, the first driving member 260 includes a first longitudinal rotation motor 262, a first reduction gear 264, and a first gearbox 266.

Specifically, the first longitudinal motor 262 provides the longitudinal power to the irradiator 280, wherein the first decelerator 264 is fixed to the first bracket 240 and the first longitudinal motor ( 262 is mounted.

In addition, the first gearbox 266 connects the first reducer 264 and the irradiator 280 and is configured to transmit the longitudinal power of the first longitudinal rotation motor 262 to the irradiator 280. At this time, the first gearbox 266 may be a longitudinal power is transmitted by the pulleys and the belt winding the pulleys, and further specific transmission means by the present invention is not limited.

On the other hand, the detector 300 is installed on the rail unit 100 and configured to detect the irradiated X-ray, and includes a second telescopic member 320 and a detector 380.

Here, the second telescopic member 320 is configured to extend and contract downward on the movable member 140.

Specifically, as shown in FIG. 5, the second telescopic member 320 includes a second telescopic bar 322 disposed below and fixed to the moving member 140 and a second telescopic bar 322 disposed on the second telescopic bar 322. 2 a winding drum 324, a second winding motor 326 for rotating the second winding drum 324, a second winding reducer 328 for reducing the rotation of the second winding motor 326, and the first winding 2, a second winding gear box 329 connecting the winding reducer 328 and the second winding drum 324 is provided.

The second telescopic bar 322 is fixed to the moving member 140 to be disposed downward, has a structure in which a plurality of unit bars overlap each other, and takes a tubular shape.

Accordingly, the second telescopic bar 322 extends downwardly by pulling the lower unit bars downward from the unit bars overlapping each other.

In addition, by raising the unit bar to the upper side so that the unit bars overlap each other again to achieve a contracted structure.

The second winding drum 324 extends downward through the inside of the second telescopic bar 322 and is configured to wind or unwind the second cable 324a connected to the lower unit bar.

At this time, the second winding motor 326 provides a rotational force of the second winding drum 324. In addition, the second winding reducer 328 connected to the first winding drum 224 slows down the rotational speed of the second winding motor 326.

In addition, the second winding gear box 329 connects the second winding reducer 328 and the second winding drum 324 to transmit the rotational force of the second winding motor 326 to the second winding drum 324. It is composed.

In addition, the irradiator 200 may further include a second bracket 340 formed at a lower end of the second telescopic member 320 and a second driving member 360 fixed to the second bracket 340. have.

At this time, the second bracket 340 is installed at the lower end of the second telescopic member 320, the second driving member 360 is fixed to the second bracket 340, the detector 380 mounted on one side It is configured to longitudinally rotate.

Specifically, the second driving member 360 includes a second longitudinal rotation motor 362, a second reduction gear 364, and a second gearbox 366.

Specifically, the second longitudinal motor 362 provides the longitudinal power to the irradiator 280, wherein the second reducer 364 is fixed to the second bracket 340 and the second longitudinal motor ( 362 is mounted.

In addition, the second gearbox 366 connects the second reducer 364 and the irradiator 280, and is configured to transmit the longitudinal power of the second longitudinal motor 362 to the irradiator 280. At this time, the second gearbox 366 may be transmitted to the longitudinal power by the pulleys and the belt winding the pulleys.

Meanwhile, in the sealing type X-ray apparatus of the present invention, the first bracket 240 is extended to the second telescopic member 320 side or the second bracket 340 is extended to the first telescopic member 320 side. The structure can be taken.

As a result, the first moving member 130 or the second moving member 140 moves closer to each other, and the first telescopic member 220 and the second telescopic member 320 are close to each other, and one of them contracts by a predetermined length. Thereby, the irradiator 280 and the detector 380 can be arranged in a straight line.

Accordingly, since the irradiator 280 and the detector 380 can be disposed on the upper and lower sides of the photographed person lying on the bed, the photographed subject can be smoothly X-rayed even when the rail member 120 is one.

Furthermore, the first driving member 260 is bent to one side with respect to the extended first bracket 240, or the second driving member 360 is disposed with respect to the extended second bracket 340. A bent structure is bent to one side. Through this, the movement of the bed is no longer restricted.

As an example, as shown in FIG. 2 of the present invention, the second bracket 340 extends toward the first telescopic member 220 and the second driving member 360 is bent and bent to take a bent structure. 380 is positioned at a distance between the second telescopic member 320 to the first telescopic member 220 by a predetermined distance and then at a predetermined distance to one side in a bending direction.

At this time, the first bracket 240 is located at a point away from the first telescopic member 220 by a predetermined distance.

Accordingly, the first telescopic member 220 or the second telescopic member 220 moves closer to each other so that the first telescopic member 220 moves closer to each other. By contracting a certain length, the irradiator 280 and the detector 380 are arranged in a straight line, and the irradiator 280 is disposed on the upper side of the photographer lying on the bed, and the detector 380 is disposed on the lower side, respectively. .

As a result, the present invention is configured as described above, the rail portion 100 is configured on the ceiling, the first telescopic member 220 and the second telescopic member 320 is moved downwardly from the ceiling to move the space, Since it can be effectively utilized, there is an advantage that there is no restriction on the movement of the bed lying by the subject.

In addition, the transverse position can be adjusted by the first moving member 130 and the second moving member 140 which are moved from the rail part 100, and the first moving member 130 and the second moving member 140. Each of the first telescopic member 220 and the second telescopic member 320 is configured to allow height adjustment freely in the vertical direction.

In addition, as the first bracket 240 is installed to rotate on the first telescopic member 220, the irradiator 280 may be horizontally rotated. In addition, the irradiator 280 and the detector 380 may be vertically rotated by the first and second driving members 260 and 360 to adjust center points with respect to each other.

Furthermore, as the irradiator 280 or detector 380 is positioned at a point away from the first telescopic member 220 and the second telescopic member 320 toward each other, the irradiator 280 and the detector 380 are in a straight line. The radiator 280 and the detector 380 can be disposed on the upper and lower sides of the photographed person lying on the bed, so that the photographed subject can be smoothly x-rayed even when the rail member 120 is one.

Accordingly, the present invention can easily and easily take an X-ray photographed at any position.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

100: rail portion 120: rail member
122: rail frame 124: guide rod
126: rack gear 130: first moving member
140: second moving member 142: main body
144: moving motor 146: reducer
148: Pinion Gear 200: Research Department
220: first telescopic member 222: first telescopic bar
224: first winding drum 224a: first cable
226: first winding motor 228: first winding reduction gear
229: first winding gear box 240: first bracket
260: first drive member 262: first drive motor
264: first drive reduction gear 266: first gear box
280: irradiator 300: detector
320: second telescopic member 322: second telescopic bar
324: 2nd winding drum 324a: 2nd cable
326: second winding motor 328: second winding reduction gear
329: 2nd winding gear box 340: 2nd bracket
360: second drive member 362: second drive motor
364: second drive reduction gear 366: second gearbox
380: Detector

Claims (14)

A rail unit configured on the ceiling;
An irradiation unit installed below the rail unit and irradiating X-rays; And
A detection unit installed below the rail unit and absorbing the irradiated X-rays;
Including,
The rail unit,
At least one rail member installed on the ceiling; And
A first moving member and a second moving member moving along the rail member;
Equipped with
The rail member,
A rail frame disposed in one direction;
A guide rod disposed along the longitudinal direction of the rail frame; And
A rack gear disposed in the rail frame in parallel with the guide rod;
Dual sealing x-ray system, characterized in that it comprises a.
delete delete The method of claim 1,
The first moving member and the second moving member, respectively,
A main body that slides along the guide rod;
A moving motor mounted to the main body;
A moving reducer connected to the moving motor; And
A pinion gear configured at an end of a rotation shaft of the movement reducer and moved along the rack gear as the gear is rotated by being engaged with the rack gear;
Dual sealing x-ray system, characterized in that it comprises a.
The method of claim 1,
The irradiation unit,
A first telescopic member installed on the first moving member and configured to extend and contract downward; And
An irradiator configured to be disposed at a lower end of the first telescopic member to irradiate the x-rays;
Dual sealing x-ray system, characterized in that it comprises a.
The method of claim 5,
The first telescopic member,
A cylindrical first telescopic bar fixed to the first movable member and having a structure in which a plurality of unit bars overlap each other;
A first winding drum which is wound downward through the inside of the first telescopic bar and winds or unwinds a first cable connected to the unit bar at the bottom;
A first winding motor for providing a rotational force of the first winding drum;
A first winding reducer fixed to the moving member and mounted with the first winding motor; And
A first winding gear box connecting the first winding reducer and the first winding drum and configured to transmit a rotational force of the first winding motor to the first winding drum;
Dual sealing x-ray system, characterized in that it comprises a.
The method of claim 5,
The irradiation unit,
A first bracket installed to transversely rotate at a lower end of the first telescopic member; And
A first driving member fixed to the first bracket and configured to vertically rotate the irradiator mounted on one side;
Dual sealing x-ray system, characterized in that it further comprises.
The method of claim 7, wherein
The first driving member,
A first longitudinal motor for providing longitudinal power to the irradiator;
A first reducer fixed to the first bracket and mounted with the first longitudinal rotation motor; And
A first gearbox connecting the first decelerator and the irradiator and configured to transfer the longitudinal power of the first longitudinal rotation motor to the irradiator;
Dual sealing x-ray system, characterized in that it comprises a.
9. The method of claim 8,
Wherein:
A second telescopic member installed on the second moving member and configured to extend and contract downward; And
A detector configured to be disposed at a lower end of the second telescopic member to absorb the irradiated X-rays;
Dual sealing x-ray system, characterized in that it comprises a.
10. The method of claim 9,
The second telescopic member,
A cylindrical second telescopic bar fixed downwardly disposed on the second moving member and having a structure in which a plurality of unit bars overlap each other;
A second winding drum which is wound downward through the inside of the second telescopic bar to wind or unwind a second cable connected to the unit bar at the bottom;
A second winding motor for providing a rotational force of the second winding drum;
A second winding reducer fixed to the moving member and mounted with the second winding motor; And
A second winding gear box that connects the second winding reducer and the second winding drum and is configured to transmit a rotational force of the second winding motor to the second winding drum;
Dual sealing x-ray system, characterized in that it comprises a.
10. The method of claim 9,
Wherein:
A second bracket fixed to the lower end of the second telescopic member; And
A second driving member fixed to the second bracket and configured to vertically rotate the detector mounted at one side;
Dual sealing x-ray system, characterized in that it further comprises.
The method of claim 11,
The second drive member,
A second longitudinal motor for providing longitudinal power to the irradiator;
A second reducer fixed to the second bracket and mounted with the second longitudinal rotation motor; And
A second gearbox which connects the second reducer and the irradiator and is configured to transfer the longitudinal power of the second longitudinal motor to the detector;
Dual sealing x-ray system, characterized in that it comprises a.
The method of claim 1,
The irradiator may include: a first telescopic member installed at the first moving member and configured to extend and contract downward; An irradiator configured to be disposed at a lower end of the first telescopic member to irradiate the x-rays; A first bracket installed to transversely rotate at a lower end of the first telescopic member; And a first driving member fixed to the first bracket and configured to vertically rotate the irradiator mounted on one side thereof.
The detection unit, the second telescopic member is installed on the second moving member, configured to extend and contract downward; A detector configured to be disposed at a lower end of the second telescopic member to absorb the irradiated X-rays; A second bracket fixed to the lower end of the second telescopic member; And a second driving member fixed to the second bracket and configured to vertically rotate the detector mounted on one side thereof.
The first bracket extends toward the second telescopic member so that the first moving member or the second moving member is moved so that the irradiator and the detector can be disposed in a straight line, or the second bracket has the first telescopic member. Dual sealing x-ray system, characterized in that extended to the side.
The method of claim 13,
The first driving member is bent to one side with respect to the extended first bracket disposed, or the second drive member is bent to one side with respect to the extended second bracket to form a bent structure. Dual sealing x-ray system.

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