KR102009085B1 - Exposure field control apparatus - Google Patents

Abstract

The present invention relates to an irradiation field adjusting device, which is arranged side by side in the X-axis direction, a pair of X-axis irradiation bar provided with a plurality of X-axis laser generating member 113 along the longitudinal direction in the longitudinal direction facing the front end (110,110a) and: arranged side by side in the Y-axis direction, the pair of X-axis irradiation bar (110, 110a) is coupled to cross, a plurality of Y-axis laser generating member 123 at the opposite end in the longitudinal direction And a pair of Y-axis irradiation bars 120 and 120a through which the moving slit 121d is inserted into the pair of X-axis irradiation bars 110 and 110a so as to be movable to cross each other. Including, but when the distance between the pair of X-axis irradiation bar (110,110a) and the pair of Y-axis irradiation bar (120,120a) is adjusted, the plurality of X-axis laser generating member 113 and the Y-axis Visually formulated by a plurality of laser lights generated from the laser generating member 123 The area is to be specified as the irradiation range, the pair of X-axis irradiation bar (110,110a) is moved along the moving slit 121d and the distance between each other to adjust the length of the X-axis irradiation area of the irradiation range An X-axis spacing adjusting unit 130; Further comprising a Y-axis spacing adjusting unit 140 to adjust the distance between the pair of Y-axis irradiation bar (120,120a) to adjust the length of the Y-axis irradiation area of the irradiation range, the plurality of X-axis laser An X-axis centered laser generating member 113a is provided at the center of the generating member 113, and a Y-axis centered laser generating member 123a is provided at the center of the plurality of Y-axis laser generating members 123. The axis centered laser generating member 113a and the Y axis centered laser generating member 123a are angled by the X axis centered laser generating member angle adjusting unit 171 and the Y axis centered laser generating member angle adjusting unit 173, respectively. It is provided to be adjustable, the X-axis center laser generating member 113a and the Y-axis center laser generating member 123a is characterized in that the angle is always adjusted so as to face the center of the irradiation range.
This makes it easy for the radiologist to visually check the irradiation range without adjusting the brightness of the lighting in the room.

Description

Field of Field Control {EXPOSURE FIELD CONTROL APPARATUS}

The present invention relates to an irradiation field adjusting device, and more particularly, to an irradiation field adjusting device that allows an operator to easily recognize the X-ray irradiation range even under indoor lighting.

X-ray imaging apparatus is a device that can examine the disease without the body incision by irradiating X-ray (X-ray) to the body of the animal or the patient, and by detecting the X-ray passing through the body of the animal or patient to be

The X-ray photographing apparatus is provided with an irradiation field adjusting device for adjusting an irradiation range of X-rays generated by the X-ray generator. Since the X-ray irradiation range cannot be adjusted while the human body directly irradiates X-rays, the irradiation field adjusting device adjusts the irradiation range by using an incandescent lamp or LED as a light source. The X-ray generator irradiates X-rays with the irradiation range controlled by the irradiation field adjusting device.

1 is a schematic diagram schematically showing a configuration of a conventional field adjusting device 20. As shown in the drawing, the conventional irradiation field adjusting device 20 is provided under the X-ray generator 10. In the conventional irradiation field adjusting device 20, the light B generated by the light source 21 is reflected by the reflection mirror 23 and irradiated downward. At this time, the diaphragm 25 for adjusting the irradiation area of the light (B) is disposed under the reflection mirror 23 to expand or narrow the irradiation area of the light (B) to adjust the irradiation range (L).

The X-ray A generated by the X-ray generator 10 is transmitted through the adjusted irradiation range and irradiated onto the bed 30.

In the conventional field adjuster 20 having such a configuration, since the incandescent lamp or the LED is used as the light source 21, the radiologist in the room using the same incandescent lamp or the LED as illumination illuminates the reflection mirror 23 in the subject's body or bed ( 30) there was a limitation that it was difficult to clearly identify the scope of the survey.

In particular, a radiographer with poor skill level has a problem of increasing the exposure amount of X-rays due to poor control of the irradiation range. There was a problem.

In order to solve this problem, the radiologist used a method such as turning off the room light or lowering the illuminance of the room light in order to clearly check the irradiation range irradiated from the irradiation field adjusting device 20. When using this method, the radiologist has to repeat the operation of turning off and then on again the indoor lighting, the copper wire during the shooting was complicated, the shooting time was delayed.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problem, and to provide an irradiation field adjusting apparatus capable of precisely adjusting the X-ray irradiation range by clearly checking the irradiation range with the naked eye in a state where the radiator is turned on.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

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The object of the present invention can be achieved by a field adjuster. Irradiation field adjusting device of the present invention, provided in the lower portion of the X-ray generating unit for adjusting the irradiation range to be irradiated X-rays, arranged side by side in the X-axis direction, a plurality of along the longitudinal direction at the front end facing X-axis laser generating member 113 and a pair of X-axis irradiation bar (110,110a) provided along the longitudinal direction: are arranged side by side in the Y-axis direction, so that the pair of X-axis irradiation bar (110, 110a) to cross Coupled, the moving slit is provided with a plurality of Y-axis laser generating member 123 along the longitudinal direction at the opposite end, the pair of X-axis irradiation bar (110, 110a) is inserted to be moved in a cross state, respectively ( 121d) includes a pair of Y-axis irradiation bars (120, 120a) formed through the longitudinal direction, and between the pair of X-axis irradiation bars (110,110a) and the pair of Y-axis irradiation bars (120,120a) When the distance is adjusted, the plurality of X-axis laser generating unit A region visually identified by a plurality of laser beams generated from the ash 113 and the Y-axis laser generating member 123 is specified as an irradiation range, and the pair of X-axis irradiation bars 110 and 110a are moved. An X-axis spacing controller 130 which moves along 121d and adjusts a distance between each other so that the length of the X-axis irradiation area of the irradiation range is adjusted; Further comprising a Y-axis spacing adjusting unit 140 to adjust the distance between the pair of Y-axis irradiation bar (120,120a) to adjust the length of the Y-axis irradiation area of the irradiation range, the plurality of X-axis laser An X-axis centered laser generating member 113a is provided at the center of the generating member 113, and a Y-axis centered laser generating member 123a is provided at the center of the plurality of Y-axis laser generating members 123. The axis centered laser generating member 113a and the Y axis centered laser generating member 123a are angled by the X axis centered laser generating member angle adjusting unit 171 and the Y axis centered laser generating member angle adjusting unit 173, respectively. It is provided to be adjustable, the X-axis center laser generating member 113a and the Y-axis center laser generating member 123a is characterized in that the angle is always adjusted so as to face the center of the irradiation range.
According to one embodiment, the pair of X-axis irradiation bar (110, 110a), each of the bar-shaped X-axis irradiation bar body 111 having a predetermined length; A plurality of X-axis laser generating members 113 coupled to the lower portion of the X-axis irradiation bar main body 111 in the longitudinal direction; It is provided at one end of the X-axis irradiation bar body 111 and includes X-axis transmission members (115, 115a) coupled to the X-axis spacing control unit 130, the Y-axis irradiation bar (120, 120a), a predetermined length A bar-shaped Y-axis irradiation bar body 121 having; It is provided on one end of the Y-axis irradiation bar body 121 and includes Y-axis transmission members (125, 125a) coupled to the Y-axis spacing control unit 140, the Y-axis irradiation bar body 121, a predetermined length An upper plate 121a having a rod shape; A lower plate 121b disposed side by side at a predetermined interval below the upper plate 121a; The vertical connecting plate 121c connecting the upper plate 121a and the lower plate 121b and having a height greater than the thickness of the X-axis irradiation bar main body 111d penetrating along the length direction is formed. The upper plate 121a is formed to protrude a predetermined length toward the irradiation range than the lower plate 121b, and the Y-axis laser is disposed at the lower end region of the upper plate 121a protruding toward the irradiation range. The generating member 123 may be disposed along the longitudinal direction.

According to one embodiment, the input unit 160 for receiving the length of the X-axis irradiation region forming the X-axis of the irradiation range and the length of the Y-axis irradiation region forming the Y-axis of the irradiation range, respectively, the X-axis Spacing control unit 130, the X-axis spacing control motor 131 is rotated forward and backward according to the length of the X-axis irradiation area input from the input unit 160; Is coupled to the drive shaft of the X-axis spacing control motor 131 is rotated, has a length corresponding to the maximum moving distance of the pair of X-axis irradiation bar body 111, coupled with the X-axis motor member (115, 115a) An X-axis driving shaft 133; The pair of X-axis irradiation bar bodies 111 which are disposed in parallel with the X-axis driving shaft 133 at the lower end of the pair of X-axis irradiation bar bodies 111 and move along the X-axis driving shaft 133. An X-axis guide bar 135 for guiding movement is provided. The X-axis driving shaft 133 has a first screw thread 133a and a second screw thread 133b in different directions from both sides of the center region in the longitudinal direction. And the transmission members 115 and 115a of the pair of X-axis irradiation bar bodies 111 are screwed to the first screw thread 133a and the second screw thread 133b, respectively. In operation, the pair of X-axis irradiation bar bodies 111 may be moved in directions opposite to each other along the X-axis driving shaft 133.

According to one embodiment, the Y-axis spacing control motor 141 is rotated forward and backward corresponding to the length of the Y-axis irradiation area input from the input unit 160; Y is coupled to the Y-axis spacing control motor 141 is rotated, has a length corresponding to the maximum moving distance of the pair of Y-axis irradiation bar body 121, Y coupled to the Y-axis motor member (125, 125a) A soccer coaxial 143; A pair of Y-axis irradiation bar bodies 121 which are disposed in parallel with the Y-axis driving shaft 143 at the lower end of the other end of the pair of Y-axis irradiation bar bodies 121 and move along the Y-axis driving shaft 143. And a Y-axis guide bar 145 for guiding movement, wherein the Y-axis driving shaft 143 has a third screw thread 143a and a fourth screw thread 143b in different directions from both sides of the center region along the longitudinal direction. And the transmission members 125 and 125a of the pair of Y-axis irradiation bar bodies 121 are screwed to the third screw thread 143a and the fourth screw thread 143b, respectively. In operation, a pair of Y-axis irradiation bar bodies 121 may be moved in directions opposite to each other along the Y-axis driving shaft 143.

In the irradiation field adjusting device of the present invention, a plurality of laser generating members are disposed in the X-axis direction and the Y-axis direction, and a pair of X-axis irradiation bars and a pair of Y-axis irradiation bars cross each other and move to the desired irradiation range of the radiologist. Selectively expose only the corresponding laser generating member to the lower part to adjust the irradiation range.

Here, the irradiation field adjusting device of the present invention uses a laser generating member so that the laser light can be easily checked with the naked eye. As a result, the radiologist can solve the conventional problem of turning off the illumination or lowering the room illumination to check the irradiation range.

In addition, the irradiation range can be easily adjusted by moving a pair of X-axis irradiation bar and a pair of Y-axis irradiation bar, there is an advantage that the control range of the irradiation range can be increased compared to the conventional method through the aperture.

1 is a schematic diagram schematically showing the configuration of a conventional field adjusting device;
Figure 2 is a perspective view showing the configuration of the irradiation field adjusting apparatus of the present invention,
3 is a cross-sectional view showing a cross-sectional configuration along the line AA of FIG.
4 is a cross-sectional view showing a cross-sectional configuration along the line BB of FIG.
Figure 5 is a block diagram schematically showing the internal configuration of the irradiation field adjusting apparatus of the present invention,
6 is an exemplary view showing an angle adjustment process of the center laser generating member of the irradiation field adjusting apparatus of the present invention;
7 and 8 are exemplary views showing a process of adjusting the irradiation range of the irradiation field adjusting apparatus of the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiment of the present invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

Figure 2 is a perspective view showing the configuration of the irradiation field adjusting apparatus 100 of the present invention as viewed from the top, Figure 3 is a cross-sectional view showing a cross-sectional configuration according to the line AA of Figure 2, Figure 4 is a line BB of Figure 2 It is sectional drawing which shows the cross-sectional structure which concerns on.

Irradiation field adjusting device 100 of the present invention is provided in the lower portion of the X-ray generator is irradiated to the subject X-ray (A in Figure 1), that is, a plurality of laser generating members provided in the X-axis direction and Y-axis direction irradiation range Reference numerals 113 and 123 denote a light emission range of a rectangular light. At this time, the laser generating members 113 and 123 can be easily identified by the radiologist visually under normal room lighting by irradiating the laser light.

As a result, the radiation emitter can easily adjust the irradiation range by narrowing or widening the rectangular emission area in which the laser generating members 113 and 123 emit light.

The irradiation field adjusting device 100 of the present invention moves along the Y-axis direction and is spaced apart or narrowed from each other, and a pair of X-axis irradiation bars 110 and 110a displaying an X-axis irradiation area of the irradiation range, and a pair of X A pair of Y-axis irradiation bars 120 and 120a coupled to intersect the axis irradiation bars 110 and 110a and moving along the X-axis direction and indicating a Y-axis irradiation area of the irradiation range, and a pair of X-axis irradiation bars 110 and 110a. Adjusting the distance between the X-axis interval adjusting unit 130 for adjusting the length of the X-axis irradiation area by adjusting the interval between the Y-axis irradiation area to adjust the distance between the pair of Y-axis irradiation bar (120,120a) A pair of Y-axis spacing adjusting unit 140, a casing 150 for receiving them, an input unit 160 for adjusting the width of the irradiation range (L), and the irradiation range (L) input from the input unit 160 To control the X-axis spacing controller 130 and the Y-axis spacing controller 140 so that the X-axis irradiation bars 110 and 110a and the pair of Y-axis irradiation bars 120 and 120a are moved. And a unit (170).

Here, the irradiation range (L) is a through area surrounded by the spacing between the pair of X-axis irradiation bar (110,110a) and the spacing between the pair of Y-axis irradiation bar (120,120a) as shown in FIG. to be. When the X-ray generator (not shown) is provided on the irradiation field adjusting device 100, the X-ray A is irradiated to the subject through the irradiation range L. FIG.

The pair of X-axis irradiation bars 110 and 110a is controlled by the X-axis spacing adjusting unit 130, and the plurality of X-axis laser generating members 113 emit light to radiate the X-axis irradiation area of the irradiation range. Make it aware. As shown in FIGS. 3 and 4, the X-axis irradiation bars 110 and 110a have a rod-shaped X-axis irradiation bar body 111 having a predetermined length and width W1, and a length on the bottom surface of the X-axis irradiation bar body 111. A plurality of X-axis laser generating member 113 coupled to a predetermined interval along the direction, and X-axis motor member 115, 115a which is provided at one end of the X-axis irradiation bar body 111 is coupled to the X-axis spacing control unit 130 And an X-axis guide coupling end 117 provided at the other end of the X-axis irradiation bar body 111 and coupled to the X-axis guide bar 135 of the X-axis transmission members 115 and 115a.

The length of the X-axis irradiation bar body 111 is the total X coupled to the X-axis irradiation bar body 111 when the pair of Y-axis irradiation bars 120 and 120a are maximally opened to both sides as shown in FIG. Both shaft laser generating member 113 is provided with a length that can be exposed to the irradiation range (L).

Accordingly, the length of the X-axis irradiation bar main body 111 is longer than the length of the area provided with the plurality of X-axis laser generating members 113 plus the width W2 of the Y-axis irradiation bar main body 121 on both sides. It is preferable.

The width W1 of the X-axis irradiation bar main body 111 is Y-axis irradiation bar when the length l2 of the Y-axis irradiation area is set to the minimum length that the radiologist can adjust, as shown in FIG. 120, 120a may be formed to a length capable of concealing all the remaining Y-axis laser generating member 123 that is not located in the irradiation range (l2), or may be manufactured using a conventional multi-stage structure. For example, when the three laser generating members 123 are located in the irradiation range L2 at the set minimum length l2 of the Y axis irradiation area, the width W1 of the X axis irradiation bar main body 111 is outside the irradiation range. The other three laser generating members 123 are formed to have a length that can cover them.

The Y-axis irradiation bars 120 and 120a have a plurality of Y-axis laser generating members 123 located in the longitudinal direction, and each of the Y-axis laser generating members 123 is supplied with power to emit light. At this time, the Y-axis laser generating member 123 outside the irradiation range must be covered to display the correct irradiation range.

To this end, as shown in (a) of FIG. 7, the pair of X-axis irradiation bars 110 and 110a and the pair of Y-axis irradiation bars 120 and 120a are coupled to cross each other so that the laser generating members (dotted lines) outside each other are irradiated. The circle marked with).

A plurality of X-axis laser generating member 113 is coupled at a predetermined interval along the longitudinal direction of the X-axis irradiation bar body 111. The X-axis laser generating member 113 may be provided with a laser generator for irradiating a laser which is visually displayed under indoor lighting or a colored LED for irradiating colored light such as red or blue. The plurality of X-axis laser generating members 113 are arranged in the same number on both sides about the X-axis center laser generating member 113a.

The X-axis laser generating member 113 is provided at the lower end of the side toward the irradiation range (L) in the X-axis irradiation bar body 111, as shown in Figure 4 (a). The X-axis laser generating members 113 provided in the pair of X-axis irradiation bars 110 and 110a are provided in directions facing each other toward the irradiation range L, respectively.

X-axis transmission member (115, 115a) is provided at one end of the X-axis irradiation bar body 111, is coupled to the X-axis spacing control unit 130 so that the X-axis irradiation bar body 111 is moved along the X-axis. X-axis transmission member (115, 115a) according to a preferred embodiment of the present invention is formed in the form of a coupling ring coupled to the X-axis drive shaft (133). The X-axis driving members 115 and 115a are screwed to the first screw thread 133a of the X-axis driving shaft 133 to linearly move along the X-axis driving shaft 133.

The X-axis guide coupling end 117 is provided at the other end of the X-axis irradiation bar body 111 to move the X-axis guide bar 135 when the X-axis driving members 115 and 115a are moved along the X-axis driving shaft 133. Is moved along. When the X-axis transmission members 115 and 115a are moved along the X-axis driving shaft 133, the X-axis guide coupling end 117 provided in the form of a free end is not moved in the same amount as the X-axis transmission members 115 and 115a. Can be deflected without.

Accordingly, the X-axis guide coupling end 117 is moved along the X-axis guide bar 135 and the entire area along the longitudinal direction of the X-axis irradiation bar body 111 can be moved along the X-axis in the same amount.

The X-axis guide wheel 118 is provided at the lower portion of the X-axis guide coupling end 117 to be idle rotated on the X-axis rotation shaft 118a. The X-axis guide wheel 118 is rotated by the force that the X-axis transmission member (115, 115a) is moved along the X-axis drive shaft 133 while being inserted into the wheel movement groove (135a) of the X-axis guide bar 135 And is moved along the wheel movement groove (135a).

A pair of Y-axis irradiation bar (120,120a) is coupled to the pair of X-axis irradiation bar (110,110a), respectively, intersected by the Y-axis spacing control unit 140 to control the space between each other and generate a plurality of Y-axis laser The member 123 emits light so that the X-ray radiologist can recognize the Y-axis irradiation area of the irradiation range.

The Y-axis irradiation bars 120 and 120a are provided at the Y-axis irradiation bar body 121, the Y-axis irradiation bar body 121, and the plurality of Y-axis laser generating members 123 for displaying the Y-axis irradiation area, and the Y-axis irradiation bar body. Y-axis transmission members 125 and 125a provided at one end of the 121 and coupled to the Y-axis spacing adjusting unit 140, and provided at the other end of the Y-axis irradiation bar main body 121 to be combined with the Y-axis guide bar 145. Y-axis guide coupling end 127 is included.

The Y-axis irradiation bar body 121 supports the X-axis irradiation bars 110 and 110a so as to be movable in the X-axis direction and should cover the X-axis laser generating member 113 outside the irradiation range below the X-axis irradiation bars 110 and 110a. To this end, the Y-axis irradiation bar (120, 120a) is formed in the form of a bar of the cross-section "c" shaped.

The Y-axis irradiation bar body 121 has a top plate 121a, a bottom plate 121b provided side by side under the top plate 121a, and a vertical connection plate connecting the top plate 121a and the bottom plate 121b ( 121c and a moving slit 121d formed through the vertical connecting plate 121c in the longitudinal direction to support the pair of X-axis irradiation bars 110 and 110a to be moved in the X-axis direction.

As shown in (a) of FIG. 2 and FIG. 3, the upper plate 121a is orthogonal to the upper portions of the X axis irradiation bars 110 and 110a, and the lower plate 121b is disposed below the X axis irradiation bars 110 and 110a. Are orthogonally located. The X-axis irradiation bars 110 and 110a are inserted through the moving slit 121d.

Here, the lower plate 121b serves to cover the X-axis laser generating member 113 provided in the lower portion of the X-axis irradiation bar (110, 110a). The upper plate 121a serves to support the plurality of Y-axis laser generating members 123. When the upper plate 121a and the lower plate 121b have the same width, the laser light or the LED light emitted from the Y-axis laser generating member 123 is blocked by the lower plate 121b.

Accordingly, the width W2 of the upper plate 121a is formed to be longer than the width W3 of the lower plate 121b by a predetermined length d. The upper plate 121a protrudes toward a predetermined length (d) irradiation range compared to the lower plate 121b, and the Y-axis laser generating member 123 is provided at the lower end of the protruding region. As a result, the light generated from the Y-axis laser generating member 123 is irradiated to the irradiation range.

Here, as shown in FIG. 3A, the width W3 of the lower plate 121b is the same as that of the width W1 of the X-axis irradiation bar body 111 described above. ) Is formed to have a length that can cover all of the remaining X-axis laser generating member 113 that is not located in the irradiation range when it is located in the minimum X-axis irradiation area (1).

The vertical connecting plate 121c connects the upper plate 121a and the lower plate 121b to each other, and a moving slit 121d is formed to support the pair of X-axis irradiation bars 110 and 110a.

A plurality of Y-axis laser generating member 123 is provided at the lower end of the upper plate 121a at regular intervals along the longitudinal direction. The Y-axis laser generating member 123 is provided in the same number on both sides about the Y-axis center laser generating member 123a. The Y-axis laser generating member 123 is also provided with a laser generator or colored LEDs similarly to the X-axis laser generating member 113.

Y-axis transmission members (125, 125a) are provided at one end of the Y-axis irradiation bar body 121, the third screw thread (143a) and the fourth screw thread (143b) of the Y-axis drive shaft 143 of the Y-axis spacing adjusting unit 140 Respectively screwed in. The Y-axis guide coupling end 127 is provided at the other end of the lower plate 121b and is coupled to the Y-axis guide bar 145.

Since the coupling structure of the Y-axis transmission members 125 and 125a and the Y-axis guide coupling end 127 is the same as the X-axis transmission members 115 and 115a and the X-axis guide coupling end 117 described above, a detailed description thereof will be omitted.

The X-axis interval adjusting unit 130 adjusts the distance between the pair of X-axis irradiation bar (110, 110a) to correspond to the X-axis irradiation area input from the input unit 160. The X-axis spacing controller 130 converts the driving force of the X-axis spacing control motor 131 into a linear movement of a pair of X-axis irradiation bar (110, 110a).

The X-axis spacing controller 130 is the X-axis spacing control motor 131 rotates forward and backward by the control signal of the control unit 170, and the X-axis driving shaft 133 coupled to the drive shaft of the X-axis spacing control motor 131 And an X-axis guide bar 135 provided in parallel with the X-axis driving shaft 133 to guide the movement of the other end of the pair of X-axis irradiation bars 110 and 110a.

The X-axis interval adjusting motor 131 is rotated forward and backward by the control unit 170 in accordance with the change in the length of the X-axis irradiation area input through the input unit 160. The X-axis driving shaft 133 is provided with a length corresponding to the maximum moving distance that the pair of X-axis irradiation bar (110,110a) is moved in the X-axis direction. The first screw thread 133a and the second screw thread 133b are formed in both directions from the center region along the X-axis driving shaft 133 in the longitudinal direction.

The X-axis transmission member 115 of the first X-axis irradiation bar 110 is screwed to the first screw thread 133a, and the X-axis transmission member 115a of the second X-axis irradiation bar 110a is attached to the second thread 133b. ) Is screwed in. When the X axis driving shaft 133 is rotated, the pair of X axis irradiation bars 110 and 110a coupled to the first screw thread 133a and the second screw thread 133b in opposite directions move away from each other, or The gap is moved to narrow.

Here, the X-axis drive shaft 133 is coupled by the bearing 134 is rotated. The bearing 134 is fixed to the inner wall surface of the casing 150 to support the X-axis drive shaft 133 to rotate stably.

The X-axis guide bar 135 is disposed at the other end of the pair of X-axis irradiation bars 110 and 110a in the X-axis direction. The X-axis guide bar 135 and the X-axis driving shaft 133 are provided side by side at both ends of the X-axis irradiation bar (110, 110a), respectively. The X-axis guide bar 135 supports the other ends of the X-axis irradiation bars 110 and 110a when the X-axis irradiation bars 110 and 110a are moved along the X-axis driving shaft 133 to guide the horizontal movement in the same amount.

On the plate surface of the X-axis guide bar 135, the wheel moving groove 135a is formed to be recessed in a predetermined depth along the longitudinal direction. As shown in FIG. 3B, the X-axis guide wheel 118 is inserted into the wheel moving groove 135a and moved.

The X-axis guide bar 135 is supported by a plurality of brackets 136 is fixed in position. The bracket 136 is fixed to the inner wall surface of the casing 150 to support the position of the X-axis guide bar 135.

The Y-axis spacing adjusting unit 140 moves the pair of Y-axis irradiation bars 120 and 120a in the Y-axis direction. The Y-axis spacing controller 140 adjusts the space between the pair of Y-axis irradiation bars 120 and 120a to be wider or narrower to correspond to the Y-axis irradiation area input from the input unit 160.

 Y-axis spacing controller 140 is Y-axis spacing control motor 141 is rotated forward and backward by the control signal of the control unit 170, and Y-axis drive shaft 143 coupled to the drive shaft of the Y-axis spacing control motor 141 And a Y-axis guide bar 145 provided in parallel with the Y-axis driving shaft 143 to guide the movement of the other end of the pair of Y-axis irradiation bars 120 and 120a.

Since the configuration and operation process of the Y-axis spacing controller 140 is the same as the X-axis spacing controller 130 described above, a detailed description thereof will be omitted.

X-axis spacing control unit 130 according to a preferred embodiment of the present invention is a moving distance of a pair of X-axis irradiation bar (110, 110a) by the screw coupling of the X-axis driving shaft 133 and the X-axis transmission member (115, 115a) However, this is only one embodiment, and in some cases, a rack and pinion, a plurality of gear trains, a driving belt, and the like may be implemented alone or in combination.

The casing 150 is provided below the X-ray generating unit (10 in FIG. 1) so that the pair of X-axis irradiation bars 110 and 110a and the pair of Y-axis irradiation bars 120 and 120a cross each other and are moved so that the irradiation range L ) To adjust. Casing 150 is fixed to the position of the X-axis spacing control unit 130 and the Y-axis spacing control unit 140, a pair of X-axis irradiation bar (110,110a) and a pair of Y-axis irradiation bar (120,120a) It can be moved smoothly.

An exposure hole 151 for exposing X-rays radiated from the X-ray generator (not shown) to the lower portion of the casing 150 is formed. The exposure hole 151 is formed with the width of the maximum irradiation range that can be adjusted by the irradiation field adjusting device 100 as indicated by the dotted lines in (a) and (b) of FIG.

5 is a schematic diagram schematically showing the internal configuration of the field adjustment device 100. As shown, the input unit 160 receives the irradiation range of the irradiation field adjusting device 100 from the radiologist. The X-axis spacing control motor 131 and the Y-axis spacing control motor 141 are driven to correspond to the length of the X-axis irradiation area and the length of the Y-axis irradiation area received from the input unit 160.

The X-axis irradiation area is controlled by the spacing interval between the pair of X-axis irradiation bar body 111, the Y-axis irradiation area is adjusted by the spacing interval between the pair of Y-axis irradiation bar body 121. The X-axis and Y-axis irradiation areas extend or narrow to both sides with respect to the center point of the irradiation range, and the length is adjusted.

The input unit 160 may be provided with an X-axis irradiation area control button and a Y-axis irradiation area control button. Each control button may receive the length of the X-axis irradiation area and the Y-axis irradiation area numerically, or may be formed of an increase button and a reduction button to receive an increase signal and a decrease signal.

For example, in a state in which the irradiation range is narrowly set as shown in FIG. 7A, when the radiation range is to be widened as shown in FIG. 7B, the radiographer operates the X-axis irradiation area control button with an increase. The Y axis irradiation area control button can be operated by increasing. The radiographer can operate the stop button when the adjusted irradiation range corresponds to the desired position and area, and again reduce the size when there is a difference from the desired irradiation range.

The input unit 160 may be implemented in the form of a remote controller or in the form of a computer so that the radiologist can easily use.

The controller 170 moves a pair of X-axis irradiation bars 110 and 110a and a pair of Y-axis irradiation bars 120 and 120a to correspond to the lengths of the X-axis irradiation area and the Y-axis irradiation area input through the input unit 160. The X-axis spacing control motor 131 and the Y-axis spacing control motor 141 to control.

The controller 170 rotates and reverses the normal and reverse directions of the X-axis interval adjusting motor 131 and the Y-axis interval adjusting motor 141 to correspond to the moving distances of the X-axis irradiation bars 110 and 110a and the Y-axis irradiation bars 120 and 120a. Control the number.

In addition, the controller 170 controls the irradiation angles such that the X-axis center laser generating member 113a and the Y-axis center laser generating member 123a always irradiate light toward the center point.

The plurality of laser generating members 113 and 123 irradiates laser or light in a vertical direction. Accordingly, the irradiation range formed by the light irradiated from the plurality of laser generating members 113 and 123 has a quadrangular shape as shown in FIGS. 7A and 7B.

The radiographer undergoes a process in which the center of the irradiation range is positioned at the center of the subject's imaging area. Accordingly, when the center is displayed on the irradiation range displayed by the laser generating members 113 and 123, the adjustment process may be more simplified.

To this end, the irradiation field adjusting device 100 of the present invention is located at the center of the X-axis center laser generating member 113a and the plurality of Y-axis laser generating members 123 located at the center of the plurality of X-axis laser generating members 113. The located Y-axis laser generating member 123a adjusts the light emitting angle to always irradiate light toward the center.

Here, the center refers to the center point of the pair of X-axis irradiation bar (110,110a) and the pair of Y-axis irradiation bar (120,120a).

The angle of the X-axis center laser generating member 113a is adjusted by the X-axis center laser generating member angle adjusting unit 171, and the Y-axis center laser generating member 123a is the Y-axis center laser generating member angle adjusting unit 173. The angle is adjusted by).

6A and 6B are exemplary views schematically illustrating a process of adjusting the angle of the X-axis center laser generating member 113a.

As shown in FIG. 6A, the X-axis center laser generating member 113a is rotatably coupled to the X-axis irradiation bar 110 by the rotation shaft 113a. When the X-axis irradiation bar 110 is located close to the center O, the X-axis center laser generating member 113a and the center O have a first angle θ1.

In this state, when the X-axis irradiation bar 110 is moved away from the center O as shown in FIG. 6 (b), the X-axis center laser generating member angle adjusting unit 171 rotates the rotation shaft 171a. The second angle θ2 is adjusted so that the X-axis center laser generating member 113a faces the center O.

The angle at which the X-axis centered laser generating member angle adjusting unit 171 rotates the X-axis centered laser generating member 113a is adjusted to be linked to the driving of the X-axis interval adjusting motor 131. The angle adjustment direction of the X-axis center laser generating member 113a is adjusted according to the positive and reverse rotation of the X-axis spacing adjusting motor 131, and the X-axis center laser generating member (according to the rotational speed of the X-axis spacing adjusting motor 131 The angle adjustment amount of 113a) is adjusted.

The X-axis centered laser generating member 113a and the Y-axis centered laser generating member 123a are always centered by the X-axis centered laser generating member angle adjusting unit 171 and the Y-axis centered laser generating member angle adjusting unit 173. It will emit light toward.

Accordingly, as shown in FIG. 7A, when the rectangular irradiation range is displayed by the lights a and b emitted from the plurality of laser generating members 113 and 123, the X-axis center laser generating member 113a is displayed. The light (c) irradiated from and the light (d) irradiated from the Y-axis center laser generating member 123a are displayed in the center region so that the radiologist can recognize the center position.

Meanwhile, the X-axis center laser generating member angle adjusting unit 171 and the Y-axis center laser generating member angle adjusting unit 173 consider the height of the subject's photographing part as well as the horizontal distance from the center O. The center laser generating member 113a and the Y-axis center laser generating member 123a are always adjusted to emit light toward the center.

The irradiation range adjusting process using the irradiation field adjusting device 100 of the present invention having such a configuration will be described with reference to FIGS. 2 to 8.

The pair of X-axis irradiation bars 110 and 110a and the pair of Y-axis irradiation bars 120 and 120a are provided below the X-ray generating unit (not shown) in a state accommodated in the casing 150. The lower part of the casing 150 is provided with a bed (30 of FIG. 1) lying on the subject.

Although not shown in the drawings, the casing 150 is provided to be movable in the X-axis direction and the Y-axis direction with respect to the bed 30. As a result, the radiologist moves the casing 150 to the upper part of the body to perform X-ray imaging of the subject lying on the bed 30.

In this state, the radiologist controls the irradiation field adjusting device 100 to adjust the irradiation range to which X-rays are to be irradiated to the body part of the subject.

The radiologist adjusts the length of the X-axis irradiation area and the Y-axis irradiation area of the irradiation range using the input unit 160, respectively.

7 and 8 is a view showing the bottom configuration viewed from the bottom of the irradiation field adjusting device 100 in an upward direction.

Figure 7 (a) is an exemplary view showing a state in which the irradiation range of the irradiation field adjusting device 100 is narrowly adjusted. The pair of X-axis irradiation bars 110 and 110a are respectively moved in opposite directions along the X-axis driving shaft 133, and the pair of Y-axis irradiation bars 120 and 120a are respectively moved in the opposite directions along the Y-axis driving shaft 143. do.

When the pair of X-axis irradiation bars 110 and 110a and the pair of Y-axis irradiation bars 120 and 120a are moved to the irradiation range input from the input unit 160, the pair of X-axis irradiation bars 110 and 110a is illustrated in FIGS. 3A and 4A. As described above, the X-axis laser generating member 113 and the Y-axis laser generating member 123 emit light.

The X-axis laser generating member 113 and the Y-axis laser generating member 123 irradiate the laser light in a vertical direction, and the X-axis center laser generating member 113a and the Y-axis center laser generating member 123a have an irradiation range. Irradiate the laser light with the center of.

At this time, the remaining X-axis laser generating member 113 that is not positioned in the irradiation range is covered by the lower plate 121b, and the remaining Y-axis laser generating member 123 that is not positioned in the irradiation range is the X-axis irradiation bars 110 and 110a. Obscured).

FIG. 7B is an exemplary diagram showing an irradiation range displayed by a laser beam on a body of a subject. As shown, the light a irradiated from the X-axis laser generating member 113 is irradiated by the first length L1 in the X-axis direction, and the light b irradiated from the Y-axis laser generating member 123 is It irradiates by 2nd length (L2) in a Y-axis direction, and shows an irradiation range. At this time, the light (c) irradiated from the X-axis center laser generating member (113a) and the light (d) irradiated from the Y-axis center laser generating member (123a) are concentrated in the center area, and the center of the irradiation range is radiated to the radiologist. Display.

Since the radiation range is indicated by the laser beam, the radiation range can be accurately identified with the naked eye even under normal lighting. This eliminates the hassle of turning off the lights or dimming the room illumination in order to confirm the conventional irradiation range.

On the other hand, when it is necessary to adjust the irradiation range wide, as shown in Figure 8 (a) a pair of X-axis irradiation bar (110,110a) and a pair of Y-axis irradiation bar (120,120a) X-axis drive shaft 133 Along with the Y-axis drive shaft 143 is moved apart from each other.

As the interval between the pair of Y-axis irradiation bars 120 and 120a and the pair of X-axis irradiation bars 110 and 110a is widened, the X-axis laser generating member 113 and Y are exposed downward through the exposure hole 151. The number of the axis laser generating members 123 is increased.

As a result, as shown in FIG. 8B, the irradiation range L3 × L4 displayed to the subject by the light emitted from the plurality of X-axis laser generating members 113 and Y-axis laser generating members 123 is obtained. It becomes wider compared with FIG.

Even in this case, the X-axis center laser generating member 113a and the Y-axis center laser generating member 123a are formed by the X-axis center laser generating member angle adjusting unit 171 and the Y-axis center laser generating member angle adjusting unit 173. The angle is adjusted to irradiate light toward the center.

As described above, in the irradiation field adjusting apparatus according to the present invention, a plurality of laser generating members are disposed in the X-axis direction and the Y-axis direction, and a pair of X-axis irradiation bars and a pair of Y-axis irradiation bars cross each other to move and radiate. Only the laser generating member corresponding to the irradiation range desired by the company can be selectively exposed downward to adjust the irradiation range.

Here, the irradiation field adjusting device of the present invention uses a laser beam that can be easily identified with the naked eye even under general lighting as a laser generating member. As a result, the radiologist can solve the conventional problem of turning off the illumination or lowering the room illumination to check the irradiation range.

In addition, the irradiation range can be easily adjusted by moving a pair of X-axis irradiation bar and a pair of Y-axis irradiation bar, there is an advantage that the control range of the irradiation range can be increased compared to the conventional method through the aperture.

The embodiments of the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. . Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents, and substitutes within the spirit and scope of the invention as defined by the appended claims.

100: irradiation field adjusting device 110, 110a: X-axis irradiation bar
111: X axis irradiation bar main body 113: X axis laser generating member
113a: X-axis center laser generating member 115,115a: X-axis transmission member
117: X-axis guide wheel 118: X-axis guide wheel
118a: X axis rotating shaft 120, 120a: Y axis irradiation bar
121: Y-axis irradiation bar body 121a: Top plate
121b: Lower plate 121c: Vertical connecting plate
121d: Moving slit 123: Y-axis laser generating member
123a: Y-axis centered laser generating member 125: Y-axis moving member
127: Y-axis guide coupling stage 128: guide wheel
130: X axis interval adjusting unit 131: X axis interval adjusting motor
133: X axis drive shaft 133a: first screw thread
133b: second thread 134: bearing
135: X axis guide bar 135a: wheel movement groove
136: bracket 140: Y axis spacing adjusting unit
141: Y axis spacing motor 143: Y axis drive shaft
143a: 3rd thread 143b: 4th thread
144: bearing 145: Y axis guide bar
145a: wheel movement groove 150: casing
151: exposure hole 160: input unit
170: control unit
A: X-ray
L: Scope of investigation

Claims (6)

In the irradiation field adjusting device is provided in the lower portion of the X-ray generating unit for adjusting the irradiation range to be irradiated the X-ray,
A pair of X-axis irradiation bars (110, 110a) are arranged side by side in the X-axis direction, the plurality of X-axis laser generating member 113 is provided along the longitudinal direction at the front end facing each other:
It is arranged side by side in the Y-axis direction, the pair of X-axis irradiation bar (110, 110a) is coupled to cross, a plurality of Y-axis laser generating member 123 is provided along the longitudinal direction at the opposite end, The pair of X-axis irradiation bars (110, 110a) is a movable slit (121d) is inserted into the movable state in the cross state, respectively, includes a pair of Y-axis irradiation bars (120, 120a) formed through the longitudinal direction,
When the distance between the pair of X-axis irradiation bars 110 and 110a and the pair of Y-axis irradiation bars 120 and 120a is adjusted, the plurality of X-axis laser generating members 113 and the Y-axis laser generating members The area visually identified by the plurality of laser lights generated from 123 is specified as the irradiation range,
The pair of X-axis irradiation bar (110, 110a) is moved along the moving slit 121d and the X-axis interval adjusting unit 130 to adjust the distance between each other to adjust the length of the X-axis irradiation area of the irradiation range Wow;
Further comprising a Y-axis spacing adjusting unit 140 to adjust the distance between the pair of Y-axis irradiation bar (120,120a) to adjust the length of the Y-axis irradiation area of the irradiation range,
An X-axis center laser generating member 113a is provided at the center of the plurality of X-axis laser generating members 113, and a Y-axis center laser generating member 123a is provided at the center of the plurality of Y-axis laser generating members 123. Is equipped,
The X-axis center laser generating member 113a and the Y-axis center laser generating member 123a are respectively controlled by the X-axis center laser generating member angle adjusting unit 171 and the Y-axis center laser generating member angle adjusting unit 173. The angle is provided to be adjustable, and the X-axis center laser generating member 113a and the Y-axis center laser generating member 123a is always adjusted to the angle so as to face the center of the irradiation range .
delete delete The method of claim 1,
The pair of X-axis irradiation bar (110, 110a), respectively,
A rod-shaped X-axis irradiation bar body 111 having a predetermined length;
A plurality of X-axis laser generating members 113 coupled to the lower portion of the X-axis irradiation bar main body 111 in the longitudinal direction;
It is provided on one end of the X-axis irradiation bar body 111 and includes an X-axis transmission member (115, 115a) coupled to the X-axis spacing control unit 130,
The Y-axis irradiation bar (120, 120a),
A bar-shaped Y-axis irradiation bar body 121 having a predetermined length;
It is provided at one end of the Y-axis irradiation bar body 121 and includes Y-axis transmission members (125, 125a) coupled to the Y-axis spacing control unit 140,
The Y-axis irradiation bar body 121,
A rod-shaped upper plate 121a having a predetermined length;
A lower plate 121b disposed side by side at a predetermined interval below the upper plate 121a;
The vertical connecting plate 121c connecting the upper plate 121a and the lower plate 121b and having a height greater than the thickness of the X-axis irradiation bar main body 111d penetrating along the length direction is formed. Include,
The upper plate 121a is formed to protrude a predetermined length toward the irradiation range than the lower plate 121b,
The Y-axis laser generating member (123) is disposed in the longitudinal direction in the lower end region of the upper plate (121a) protruding toward the irradiation range, characterized in that the device.
The method of claim 4, wherein
And an input unit 160 which receives an X-axis irradiation area length forming an X axis of the irradiation range and a Y-axis irradiation area length forming the Y axis of the irradiation range, respectively.
The X-axis interval adjusting unit 130,
An X-axis interval adjusting motor 131 which is rotated forward and backward according to the length of the X-axis irradiation area input from the input unit 160;
Is coupled to the drive shaft of the X-axis spacing control motor 131 is rotated, has a length corresponding to the maximum moving distance of the pair of X-axis irradiation bar body 111, coupled with the X-axis motor member (115, 115a) An X-axis driving shaft 133;
The pair of X-axis irradiation bar bodies 111 which are disposed in parallel with the X-axis driving shaft 133 at the lower end of the pair of X-axis irradiation bar bodies 111 and move along the X-axis driving shaft 133. X-axis guide bar 135 to guide the movement,
The X-axis driving shaft 133 is formed with a first screw thread 133a and a second screw thread 133b in different directions from both sides of the center region along the longitudinal direction.
The transmission members 115 and 115a of the pair of X-axis irradiation bar bodies 111 are screwed to the first screw thread 133a and the second screw thread 133b, respectively, to drive the X-axis spacing control motor 131. A pair of X-axis irradiation bar main body 111 is moved in the opposite direction along the X-axis driving shaft 133, characterized in that the device for adjusting the field.
The method of claim 5,
A Y-axis spacing control motor 141 which is rotated forward and backward to correspond to the length of the Y-axis irradiation area input from the input unit 160;
Y is coupled to the Y-axis spacing control motor 141 is rotated, has a length corresponding to the maximum moving distance of the pair of Y-axis irradiation bar body 121, Y coupled to the Y-axis motor member (125, 125a) A soccer coaxial 143;
A pair of Y-axis irradiation bar bodies 121 which are disposed in parallel with the Y-axis driving shaft 143 at the lower end of the other end of the pair of Y-axis irradiation bar bodies 121 and move along the Y-axis driving shaft 143. Y-axis guide bar 145 for guiding movement,
The Y-axis driving shaft 143 is formed with a third screw thread 143a and a fourth screw thread 143b in different directions from both sides of the center region along the longitudinal direction.
The transmission members 125 and 125a of the pair of Y-axis irradiation bar bodies 121 are screwed to the third thread 143a and the fourth thread 143b, respectively, so as to drive the Y-axis spacing control motor 141. Y-axis irradiation bar body 121 of the pair is irradiated field adjustment device, characterized in that moved in the opposite direction along the Y-axis drive shaft (143).

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