RU2724202C1 - Portable type x-ray image former - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to medical equipment field. Portable X-ray image former comprises: a portable main body having an image forming button and configured to carry, a radiation emitter configured to emit radiation through a guide tube extending from the center of said portable main body, and a radiation detector configured to detect radiation emitted from said emitter and transmitted through the object, wherein the radiation detector is configured to measure the distance to the object when the radiation detector is set to the image forming preparation mode, wherein distance from said radiation emitter is measured when distance to object is within preset proximity control distance, wherein resolution of image generation permission is transmitted to said radiation emitter when separation distance from said radiation emitter is greater than or equal to preset control separation distance, wherein said emitter is configured to emit radiation in response to actuation of an image forming button when a resolution signal for generating an image is obtained, and do not emit radiation independently of actuation of said image forming button, if resolution of image generation is not obtained from radiation detector.EFFECT: technical result of the disclosed invention is higher user safety.5 cl, 4 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a portable x-ray imager and, in particular, to a portable x-ray imager capable of forming images while maintaining a safe distance from the object.

BACKGROUND

Currently, the x-ray machine is widely used in the field of medicine as an important tool for obtaining images of the internal part of the human body.

The x-ray apparatus comprises an x-ray generator and an x-ray detector used to be arranged at a predetermined distance from each other, while it can photograph an x-ray image of an object by placing an x-ray detector behind the object and irradiating the front of the object with x-rays.

Since portable X-ray devices are used at arbitrary locations rather than fixed locations, there are many cases where means of preventing radiation exposure at the place of use are insufficient.

Such a portable X-ray device has been disclosed in various embodiments, for example, Korean Patent Publication No. 10-2017-0024057.

However, since such a portable X-ray machine is simple and easy to operate, unintentional exposure may occur due to carelessness of the user or lack of preparation for use.

Thus, a portable x-ray apparatus is required to ensure safety in order to reduce the harm from radiation exposure due to x-ray irradiation of an indefinite number of people around the user.

SUMMARY OF THE INVENTION

Technical problem

The present invention was created to meet the above requirements, and its task is to provide a portable X-ray imager capable of emitting radiation, while guaranteeing the safety of radiation exposure for the object.

Solution to the problem

To solve this problem, a portable x-ray image former according to the present invention is proposed, comprising a portable main body having an image forming button and configured to be transferred; a radiation emitter configured to emit radiation through a guide tube extending from the center of said portable main body; and a radiation detector configured to detect radiation emitted from said radiation emitter and transmitted through an object, wherein the radiation detector is configured to measure a distance to an object when said radiation detector is set to an imaging preparation mode, wherein a distance from said radiation emitter is measured when the distance to the object is within the set reference distance of the proximity, the image-forming permission signal is transmitted to the specified radiation emitter when the separation distance from the specified radiation emitter is greater than or equal to the established control separation distance, and the specified radiation emitter is configured to emit radiation in response to the operation of the imaging button when an image forming permission signal is received, and not to emit radiation regardless of the operation of the specified button and imaging, if the imaging permission signal is not received from the radiation detector.

According to one aspect of the invention, said proximity control distance is from 5 to 10 cm, wherein said reference separation distance is in the range of 50 to 70 cm.

Additionally, it is required that said radiation emitter counts the time based on the time of the radiation at which the radiation is emitted, by receiving the response signal of the image forming button after receiving the image forming permission signal, not allow emission of radiation to prevent image formation when the button response signal of the image formation was obtained during the pause control time set from the specified time of the radiation, it was possible to form the images so that the radiation is emitted when the response signal of the image forming button is received after the control pause time set from the specified time of the radiation.

More preferably, said radiation emitter has a brass plate embedded in a portable main body, wherein said radiation detector is configured to calculate a separation distance from said radiation emitter using a metal detection sensor detecting said brass plate.

In addition, the portable main body may further comprise a display unit for the direction of the irradiation zone for irradiating the mark for visual recognition of the irradiated radiation zone emitted through the guide tube.

Technical effects of the invention

The portable X-ray imager according to the present invention allows control of the emitted radiation, while ensuring safety for the object.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a view showing a portable X-ray imager according to the invention.

FIG. 2 is a block diagram illustrating a control system of the portable X-ray imager of FIG. 1.

FIG. 3 is a flowchart illustrating an image forming process of the portable X-ray imager of FIG. 1.

FIG. 4 is a sectional view illustrating an example of a display unit of a direction of an irradiation zone of FIG. 2.

DETAILED DESCRIPTION OF THE INVENTION

A portable X-ray imager according to an embodiment of the present invention is described in more detail below with reference to the accompanying drawings.

FIG. 1 is a view showing a portable X-ray imager according to the present invention, FIG. 2 is a block diagram showing the control system of the portable X-ray imager of FIG. 1

The portable X-ray imager 100 according to the present invention of FIG. 1 and 2 includes a radiation emitter 110 and a radiation detector 160.

As shown in FIG. 1, 2, the portable X-ray imager 100 according to the present invention includes a radiation emitter 110 and a radiation detector 160.

The emitter 110 of the radiation includes a portable main body 120, made with the possibility of transfer, the working unit 130, the generator 143 of the x-ray radiation unit 145 displaying the direction of the irradiation zone, the unit 147 for transmitting radiation data and the control unit 141 radiation.

The portable main body 120 has a structure having a body part 120a made in the form of a rectangular casing and a guide tube 120b extending from the center of the body part 120a.

The portable housing 120 may perform imaging in a state in which the user grips it with his hand.

The guide tube 120b has a hollow structure, while the inner wall is made of a material that protects against radiation, for example, lead.

The work unit 130 may perform a maintenance function.

The operation unit 130 has an image forming button 131 made open on the upper surface of the portable main body 120, and a power button 133 for turning the power on / off.

An x-ray generator 143 is integrated in the housing portion 120a of the portable main body 120, so that x-rays, which are radiation, can be emitted through the guide tube 120b.

The x-ray generator 143 is controlled by driving by means of a radiation control unit 141.

The irradiation zone direction display unit 145 is mounted on the housing portion 120a around the guide tube 120b for irradiating the mark, so that the irradiation zone of the radiation emitted through the guide tube 120b can be visually recognized.

An irradiation zone direction display unit 145 may be provided on the structure for irradiating a mark forming a linear beam in the form of a rectangular border.

As shown in FIG. 4, the display portion of the direction of the irradiation zone is such that the upper casing 152 can be screwed forward and backward relative to the lower casing 151, and a laser diode 153 is mounted on the lower casing 151, and a linear beam irradiation unit 145a having a structure can be provided in which, on the upper casing 152, a focusing lens 154 and a linear filter 155 are mounted, and a spring 156 is installed between the focusing lens 154 and the lower casing 151.

In this case, the line filter 155 is configured to filter the emitted light in the form of a line with respect to the light passing through the focusing lens 154.

When the irradiation zone direction display unit 145 is designed to display a closed line rectangular line, four linear beam irradiation units can be provided to cover each side of the rectangular line.

In contrast, the irradiation zone direction display unit 145 can be designed such that only the angular portion of the area of the rectangular boundary that includes the irradiation zone is displayed.

Further, unlike the example shown, the irradiation zone direction display unit 145 may be designed to display labels for guiding the irradiation zone in various forms, such as a circle or a cross.

The radiation data transmission unit 147 is controlled by the radiation control unit 141 for wireless communication with the radiation detector 160.

The radiation control unit 141 processes the signal received from the operation unit 130 and controls the actuation of the X-ray generator 143 and the radiation area direction display unit 145.

A detailed control process of the radiation control unit 141 is described below.

The radiation detector 160 is configured to detect radiation, i.e. x-rays emitted by the emitter 110 of the radiation and transmitted through the object 10.

The radiation detector 160 includes an object distance measuring unit 161, an image distance measuring unit 163, a detection operation unit 164, a detection display unit 165, an X-ray detection unit 166, a detection data transmission unit 167, and a detection control unit 169.

Block 161 measuring the distance to the object is used with a sensor that can measure the distance from the object 10 on the radiation detector 160 facing the object 10.

The object distance measuring unit 161 may use various known detectors, such as a lidar sensor, an ultrasonic sensor, an optical sensor, and the like, which can measure distance.

Block 163 measuring the distance to the image formation site measures the separation distance between the radiation detector 160 and the emitter 110 of the radiation and provides the measurement result to the control unit 169 detection.

Block 163 measuring the distance to the image formation site uses a metal detection sensor having a primary coil and a secondary coil located perpendicular to each other to respond to eddy currents generated by the metal, the radiation emitter 110 having a structure in which the brass plate 125 is detected as metal .

The unit 163 for measuring the distance to the image forming site is designed to calculate the separation distance of the radiation emitter 110 from the signal level for detecting metal.

In contrast to the example shown, the unit 163 measuring the distance to the image formation site can be designed to calculate the distance from the emitter 110 of the radiation.

The detection operation unit 164 may perform a maintenance function.

The detection operation unit 164 may set the imaging preparation mode.

In this case, the imaging preparation mode can be set using the signal operation or a separate mode setting button.

The detection display unit 165 is controlled by the detection control unit 169 to display the display information.

The x-ray detector 166 generates image information corresponding to the incident x-rays, and transmits the image information to the detection controller 169.

The detection data transmission unit 167 is controlled by the detection control unit 169 for communication with the radiation emitter 110.

Below with reference to FIG. 3, the control process of the detection control unit 169 is described.

The detection control unit 169 determines whether a signal set in the imaging preparation mode has been received from the detection operation unit 164 (step 210).

If it is determined at step 210 that the imaging preparation mode is set, then a mutual connection is made for communication with the radiation emitter 110 (step 220).

Then, the distance to the object measuring unit 161 controls for measuring the distance from the object 10, and it is determined from the measurement result whether the distance between the object 10 and the radiation detector 160 is within the set reference proximity distance, i.e. smaller than it (step 230).

In this case, the proximity control distance can be suitably set in accordance with the use of the device, preferably from 5 to 10 cm, if the object is a human body.

If it is determined at step 230 that the distance between the object 10 and the radiation detector 160 is not within the set reference proximity distance, then a message indicating the approximation is output (step 240).

In this case, an approximation message may be composed by processing content suggesting movement to the radiation detector 160 to be displayed on the detection display unit 165.

If it is determined at step 230 that the distance between the radiation detector 10 and the radiation detector 160 is within the set proximity control distance, the separation distance between the radiation detector 160 and the radiation emitter 110 is measured, and it is determined whether the separation distance between the radiation emitter 110 is greater than the established reference separation distance or equal to it (step 250).

Here, the control separation distance can accordingly be applied depending on the use of the device, it is preferable to use from 50 to 70 cm when the object is a human body.

At step 250, when the separation distance is equal to or greater than the control separation distance, an image forming permission signal is transmitted to the emitter 110 to allow execution of the image forming button commands (step 270).

In other words, if the image forming button is triggered after the image forming permission signal is received by the radiation emitter 110 after step 270, then the radiation control unit 141 controls the x-ray generator 143 to emit x-rays.

In contrast, if it is determined at step 250 that the separation distance is less than the reference separation distance, a separation notification message is output.

A separation indicating message may be structured such that the radiation emitter 110 processes the content suggesting additional movement from the radiation detector 160 to be displayed on the detection display unit 165.

In other words, if, after step 260, the image forming permission signal is not received from the radiation detector 160, then the radiation emitter 110 acts so that the radiation is not emitted regardless of the operation of the image forming button 131.

In this case, the radiation emitter 110 counts the time based on the time of the radiation at which the response signal of the image forming button 131 is received after the image forming permission signal is received for emitting radiation, does not allow emission of radiation so that image formation is not allowed when the signal the operation of the imaging button is obtained within the control pause time set from the radiation point. In other words, the emitter 110 of the radiation processes the radiation from the generator 143 of the x-ray radiation so that it does not emit, even if the imaging button is activated during the control pause time.

In addition, the emitter 110 of the radiation allows the image formation to process the radiation for emission when the response signal of the image forming button is received after the control pause time set from the moment of radiation.

In this case, it is possible to prevent excessive exposure of the radiation to the object due to improper operation of the imaging button during the pause control period.

In this case, the radiation control unit 141 processes the mark for irradiation and display by the irradiation zone direction display unit 145 when the image forming button 131 is triggered after the image forming permission signal.

In addition, although not shown, the radiation control unit 141 may be configured to display information related to imaging for visual recognition through a separate projection device.

A portable X-ray imager allows you to control the emitted radiation, while ensuring safety for the object.

LIST OF REFERENCE NUMBERS

100 x-ray imager

110 emitter

120 portable main body

130 work block

131 imaging button

133 power button

141 radiation control unit

143 x-ray generator

145 exposure display unit

147 radiation data transmission unit

160 radiation detector

161 unit for measuring the distance to the object

163 unit for measuring the distance to the image formation site

165 detection display unit

167 detection data transmission unit

Claims (9)

1. A portable X-ray imager, comprising: a portable main body having an image forming button and configured to carry; a radiation emitter configured to emit radiation through a guide tube extending from the center of said portable main body; and a radiation detector configured to detect radiation emitted from said radiation emitter and transmitted through an object, while the radiation detector is configured to measure the distance to the object when the specified radiation detector is set to the imaging preparation mode, and the distance from the specified radiation emitter is measured when the distance to the object is within the set reference proximity distance, while the image resolution signal is transmitted to the specified radiation emitter when the separation distance from the specified radiation emitter is greater than or equal to the established control separation distance, wherein said radiation emitter is configured to emit radiation in response to the operation of the image forming button when the image forming permission signal is received, and not to emit radiation, regardless of the operation of the specified image forming button, if the resolution signal for image formation is not received from the radiation detector. 2. A portable X-ray imager according to claim 1, wherein said proximity control distance is from 5 to 10 cm, wherein said reference separation distance is in a range of 50 to 70 cm. 3. The portable x-ray imager according to claim 1, wherein said radiation emitter is configured to count time based on a point in time of the radiation at which the radiation is emitted by receiving a response signal of an image forming button after receiving an image forming permission signal, with the ability to prevent emission of radiation in order to prevent image formation when the response signal of the image forming button is received within a control pause time set from a specified time of the radiation, and with the ability to allow image formation so that radiation is emitted when the response signal of the image forming button is received after the control pause time set from the specified point in time of radiation. 4. The portable X-ray image generator according to claim 1, wherein said radiation emitter has a brass plate integrated in a portable main body, wherein said radiation detector is configured to calculate a separation distance from said radiation emitter using a metal detection sensor detecting said brass plate . 5. The portable x-ray imager according to claim 1, wherein said portable main body further comprises a display unit for the direction of the irradiation zone for irradiating the mark for visual recognition of the irradiated radiation zone emitted through the guide tube.

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