KR102535347B1 - Intraoral sensor accomodating device and intraoral sensor assembly having the same - Google Patents

Abstract

The present invention, a main body having an accommodation space in which an oral imaging sensor is accommodated; a cover coupled to the main body to cover the accommodation space; A test installed on the cover and disposed before the oral cavity imaging sensor so that irradiation light emitted from the light irradiation device in a state in which the cover covers the accommodation space is transmitted while traveling to the oral cavity imaging sensor located in the accommodation space. subject; and a fixing unit configured to fix the cover to the main body so that the test object remains aligned with the oral cavity sensor along the optical path, and comprising the same. An oral imaging sensor assembly is provided.

Description

Oral imaging sensor storage device and intraoral imaging sensor assembly having the same

The present invention relates to a case for accommodating an oral imaging sensor and an assembly in which the intraoral imaging sensor is accommodated in the case.

In general, an intraoral sensor is required to perform radiographic imaging of an oral structure during dental treatment. The intraoral imaging sensor receives light emitted from an external light irradiator while being located in the patient's mouth. An oral imaging sensor is an image sensor that detects light passing through an imaging object and converts it into an electrical signal including projection data of the imaging object, for example, teeth and alveolar bone.

However, the light irradiation device inevitably has a difference in radiation output for each product. Furthermore, the radiation output should be different depending on a radiographic target, for example, whether a tooth is an anterior tooth, a premolar tooth, or a molar tooth. Therefore, prior to radiating light to the oral cavity imaging sensor, it is necessary to set how long the radiation is to be radiated from the corresponding light irradiation device for each subject.

For this setting, a test object that can replace the imaging object and a jig on which the intraoral imaging sensor is seated are required. These objects and jigs are stored in a storage bag separate from the oral imaging sensor. Accordingly, in order to set the radiation dose of the light irradiation device, a separate tool is required, and preparation, storage, and setting processes for it are complicated and difficult.

One object of the present invention, as a preparation process for using an oral imaging sensor, is an oral imaging sensor housing device and providing the same, which makes it possible to conveniently prepare and store tools necessary for setting the radiation dose output in a light irradiation device. To provide an intraoral imaging sensor assembly.

Another object of the present invention is to provide an oral imaging sensor housing device and a device for storing the oral imaging sensor so that a user of the oral imaging sensor can simply perform a process of obtaining its setting information through light irradiation of a light irradiation device for the oral cavity imaging sensor. To provide an intraoral imaging sensor assembly.

An oral cavity imaging sensor storage device according to an aspect of the present invention for realizing the above object includes a main body having an accommodation space in which an oral cavity imaging sensor is accommodated; a cover coupled to the main body to cover the accommodation space; A test installed on the cover and disposed before the oral cavity imaging sensor so that irradiation light emitted from the light irradiation device in a state in which the cover covers the accommodation space is transmitted while traveling to the oral cavity imaging sensor located in the accommodation space. subject; and a fixing unit configured to fix the cover to the main body so that the test subject remains aligned with the intraoral imaging sensor along the light path.

Here, when the oral imaging sensor is composed of a light sensing unit for receiving the transmitted light transmitted through the test object, and a cable for transmitting the data converted by detecting the transmitted light in the light sensing unit to an external computing device, The main body, the bottom; a side wall protruding from the bottom to define the receiving space in an open top; and a passage hole opened in the sidewall to provide a passage through which the cable extends to the external computing device.

Here, it further includes a support accommodated in the accommodating space, wherein the support includes: a first seating groove in which the light sensing unit is seated; a second seating groove communicating with the first seating groove and receiving the cable; and a third seating groove communicating the second seating groove and the passage hole.

Here, the cover may include an outer skin and an inner skin that are laminated to each other, and the test object may be disposed parallel to the oral imaging sensor between the outer skin and the inner skin.

Here, the cover may include a fiducial mark indicating a region corresponding to the test object in a direction along the light path.

Here, the test object may include a plurality of target regions having different thicknesses.

An oral imaging sensor storage device according to an aspect of the present invention includes an oral imaging sensor including a light sensing unit for receiving light and a cable for transmitting data generated by light detected by the light sensing unit to an external computing device. An oral cavity imaging sensor housing device for accommodating an oral cavity imaging sensor, comprising: a main body having an accommodation space in which the oral cavity imaging sensor is accommodated; a cover coupled to the main body to cover the accommodation space; and a test object installed on the lid and disposed in front of the oral cavity imaging sensor so that the irradiated light emitted from the light irradiation device passes through the oral cavity imaging sensor, wherein the main body includes the cover covering the main body. In the covered state, the cable extends to the outside of the main body and is connected to the external computing device so that the light sensing unit receives the transmitted light transmitted through the test object and sends converted data to the external computing device. A through hole may be further included.

Here, the cover includes an outer skin and an inner skin that are laminated to each other, and the test object is disposed between the outer skin and the inner skin and may be arranged in parallel with the oral imaging sensor.

Here, it may further include a fixing unit that fixes the cover to the main body so that the test subject remains aligned along the light path with respect to the oral cavity imaging sensor.

An oral cavity imaging sensor assembly according to another aspect of the present invention includes an oral cavity imaging sensor having a photodetector for receiving light and a cable for transmitting data sensed by the photodetector to an external computing device; and an oral cavity imaging sensor storage device accommodating the oral cavity imaging sensor, wherein the oral cavity imaging sensor storage device includes: a case body having an accommodation space in which the oral cavity imaging sensor is seated; and a test object installed in the case body and disposed in front of the oral cavity imaging sensor so that the irradiation light emitted from the light irradiation device passes through the oral cavity imaging sensor, wherein the test object includes the external computing device. May be used to calculate information for determining the dose of the light irradiation device based on data obtained by receiving and converting the transmitted light transmitted through the test object by the light sensing unit.

Here, the case body includes a main body having an accommodation space in which the intraoral imaging sensor is accommodated; And a cover coupled to the main body to cover the accommodation space, wherein the cover includes an outer skin and an inner skin that are laminated to each other, the test object is disposed between the outer skin and the inner skin, and the oral cavity photographing sensor can be arranged parallel to

An oral cavity imaging sensor storage device according to another aspect of the present invention includes a main body having an accommodation space in which an oral cavity imaging sensor is accommodated; a cover coupled to the main body to cover the accommodation space; And a test object installed on the cover and disposed in front of the oral cavity imaging sensor so that the irradiation light emitted from the light irradiation device passes through the oral cavity imaging sensor, and the test object is installed on the cover , An optical sensing unit arranged in parallel with the oral imaging sensor, and the intraoral imaging sensor receiving the transmitted light passing through the test object, and transmitting the converted data by detecting the transmitted light in the optical detection unit to an external computing device. In the case where the test object is composed of a cable for the test object, the external computing device provides information for determining the dose of the light irradiation device based on data obtained by receiving and converting the transmitted light transmitted through the test object by the light sensing unit. It may be used to calculate

According to the oral cavity imaging sensor storage device according to the present invention configured as described above and the oral cavity imaging sensor assembly having the same, a test subject is installed in the cover coupled to the body in which the oral cavity imaging sensor is accommodated, and furthermore, a fixing unit fixes the cover to the main body. By fixing to , the test object is fixed on the light path from the light irradiation device to the intraoral imaging sensor, and receives light from the light irradiation device in the operation for setting the radiation dose of the light irradiation device, and the light transmitted therethrough. Let's proceed with this intraoral imaging sensor. With this configuration, there is no need to separately prepare a test object or to provide a jig or the like for using the test object, and it is possible to simply obtain information for the setting by irradiating light to the storage device of the oral cavity imaging sensor.

1 is a perspective view showing a relationship between an intraoral imaging sensor storage device 100 and a light irradiation device LE according to an embodiment of the present invention.
FIG. 2 is an internal perspective view showing the oral cavity imaging sensor 200 stored in the oral cavity imaging sensor storage device 100 of FIG. 1 and opening the cover 130 in a use state used for setting the light irradiation device LE.
FIG. 3 is a partial cross-sectional view of a coupled state between the test object 150 and the cover 130 in FIG. 2 .
FIG. 4 is an external perspective view of the oral cavity imaging sensor storage device 100 of FIG. 2 in which the cover 130 is closed.
5 is a perspective view of the test subject 150 of FIG. 2 .

Hereinafter, an oral cavity imaging sensor storage device and an oral cavity imaging sensor assembly including the device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this specification, the same or similar reference numerals are assigned to the same or similar components even in different embodiments, and the description is replaced with the first description.

1 is a perspective view showing the relationship between an oral imaging sensor storage device 100 and a light irradiation device LE according to an embodiment of the present invention, and FIG. 2 is an intraoral imaging sensor storage device 100 of FIG. 1 It is an internal perspective view showing the lid 130 opened in a use state in which the sensor 200 is accommodated and used for setting the light irradiation device LE.

Referring to the drawings, the storage device 100 may be a box in the shape of a substantially rectangular parallelepiped. The oral cavity imaging sensor 200 is accommodated in such a storage device 100 . In order to correct the radiation dose of the light irradiation device LE for irradiating light (radiation) to the intraoral imaging sensor 200, the light irradiation device LE directs the light toward the reference mark 139 in the state of FIG. 1 . will output Thereby, a light path (LP) in which light travels from the light irradiation device (LE) to the light detection unit 210 of the oral imaging sensor 200 through the reference mark 139 and the test object 150 is formed. It can be.

First, the storage device 100 may include case bodies 110 , 120 , and 130 , a test object 150 , and a fixing unit 170 .

The case bodies 110, 120, and 130 are configured to accommodate the oral cavity imaging sensor 200. Specifically, it may be composed of a main body 110, a support 120, and a cover 130.

The main body 110 may have a shape of a rectangular container with an open top. The main body 110 may be specifically composed of a bottom 111 (see FIG. 4) and a side wall 115 (see FIG. 4) protruding therefrom to form the accommodation space 113. When the floor 111 is rectangular, the side walls 115 may be formed to define the rectangular accommodation space 113 corresponding to its four sides. A through hole 117 may be opened in one region of the side wall 115 .

The support 120 is disposed within the accommodating space 113 and may be a block corresponding to the shape of the accommodating space 113 . In this embodiment, the support 120 is formed in a rectangular parallelepiped shape corresponding to the rectangular parallelepiped receiving space 113 . A seating groove in which the oral imaging sensor 200 is seated may be concavely formed in the support 120 . The seating groove may have a first seating groove 121 , a second seating groove 123 , and a third seating groove 125 .

If the first seating groove 121 is a space where the light sensing unit 210 of the oral imaging sensor 200 is seated, the second seating groove 123 is a space where the cable 250 of the oral imaging sensor 200 is seated. am. The second seating groove 123 communicates with the first seating groove 121 and may also have a toroidal cross section for winding the cable 250 . The third seating groove 125 is formed to communicate the second seating groove 123 and the through hole 117 . Due to the third seating groove 125 and the through hole 117, the cable 250 may extend outside the main body 110 to be connected to an external computing device.

The cover 130 is configured to be coupled to the main body 110 and disposed to cover the accommodation space 113 . The cover 130 may be formed of the same paper material as the body 110 . Of the cover 130 , the main portion 131 may have an area corresponding to the accommodating space 113 . Furthermore, the peripheral portion 135 of the cover 130 may extend from the main portion 131 and have a region corresponding to the side wall 115 . The reference mark 139 may be formed by being printed on the outer surface of the main portion 131 . The fiducial mark 139 is printed on an area corresponding to the oral cavity photographing sensor 200 accommodated in the accommodating space 113, specifically, the photodetector 210.

The test object 150 may be installed on the case bodies 110 , 120 , and 130 , specifically the cover 130 . The test object 150 may be embedded inside the cover 130 . An area of the lid 130 where the test object 150 is located is an area corresponding to the fiducial mark 139 and the light sensing unit 210 . Thereby, the test subject 150 is positioned in front of the oral cavity sensor 200 in the light path LP leading from the light irradiation device LE through the reference mark 139 to the light sensing unit 210. will do The test object 150 has a plate shape and may be disposed parallel to the light sensing unit 210 .

The fixing unit 170 is a component for fixing the cover 130 to the main body 110 in a state where the cover 130 covers the accommodating space 113 of the main body 110 . The fixed unit 170 may have a magnet 171 and a metal member (not shown) corresponding thereto. If the magnet 171 is installed on the periphery 135 of the cover 130, the metal member may be installed on the sidewall 115 of the main body 110 to correspond to the magnet. According to the magnetic coupling between the magnet 171 and the metal member, the test object 150 installed on the cover 130 is aligned along the light path LP with respect to the light sensing unit 210 seated on the main body 110. status can be maintained. Alternatively, the fixing unit 170 may be composed of Velcro, snap buttons, and the like.

The intraoral photographing sensor 200 may include a photodetector 210 and a cable 250. The light detecting unit 210 generates data by receiving transmitted light emitted from the light irradiation device LE and transmitted through an object to be photographed. Corresponding data is transmitted to an external computing device connected through cable 250 . The external computing device is a device having an arithmetic capability capable of processing data, and may be, for example, a personal computer. The free end of cable 250 may have a jack for connecting to a port of an external computing device.

In the above, the installation form of the test object 150 will be described with reference to FIG. 3 . FIG. 3 is a partial cross-sectional view of a coupled state between the test object 150 and the cover 130 in FIG. 2 .

Referring to this figure, the main portion 131 of the cover 130 may be formed in a laminated structure between an outer shell 132 and an inner shell 133. The test object 150 is located between the outer shell 132 and the inner shell 133, and may be disposed parallel to the outer shell 132 and the inner shell 133.

To this end, a concave space corresponding to the test subject 150 is formed in the endothelium 133, and the test subject 150 can be seated therein. As a result, no structural traces are left in the area where the test subject 150 is placed in the outer skin 132, and the area where the test subject 150 exists only protrudes from the inner skin 133, indicating the existence of the test subject 150. become recognizable. A fiducial mark 139 is printed on the outer shell 132 in a region corresponding to the test object 150, and the user can recognize the existence of the test object 150 from the outside through the mark.

Next, the passage hole 117 will be further described with reference to FIG. 4 . FIG. 4 is an external perspective view of the oral cavity imaging sensor storage device 100 of FIG. 2 in which the cover 130 is closed.

Referring to this drawing, the through hole 117 may be formed at the upper end of the side wall 115 . As a result, the through hole 117 may have a shape open toward the cover 130 .

As a result, the cable 250 of the oral imaging sensor 200 can be extended to the outside through the third seating groove 125 (see FIG. 2 ) and the passage hole 117 to be connected to an external computing device. Even in the externally extended state of the cable 250, the cover 130 can be closed to cover the accommodating space 113 and also fixed to the main body 110 using the fixing unit 170.

As a result, while the test object 150 and the light sensing unit 210 are firmly maintained in an aligned state along the light path LP, the data generated by the light sensing unit 210 is transferred to the outside through the cable 250. It can be seamlessly transferred to a computing device.

Now, the test subject 150 will be described with reference to FIG. 5 . 5 is a perspective view of the test subject 150 of FIG. 2 .

Referring to this figure, the test object 150 may have a substantially rectangular plate shape. In terms of material, the test object 150 may be formed of metal.

The test object 150 may be divided into a plurality of target regions 151 , 153 , and 155 . These target areas are of different thicknesses. Specifically, if the first target region 151 is the thinnest, the second target region 153 is thicker, and the third target region 155 is the thickest.

If the first target region 151 corresponds to the patient's anterior teeth, the second target region 153 corresponds to the premolar teeth, and the third target region 155 corresponds to the molar teeth. This corresponds to the fact that the structure density is different for each tooth.

Now, a method of setting the radiation dose of the light irradiation device LE will be described by putting together FIGS. 1 to 5 .

First, the user opens the cover 130 of the storage device 100, confirms that the light sensing unit 210 is seated in the first seating groove 121, and then the cable 250 passes through the third seating groove 125. It just needs to be extended to the outside through the passage hole 117. Connect the cable 250 to an external computing device and run a program related to it.

A user may cover the cover 130 so that the test object 150 is aligned with the light sensing unit 210 . In order to firmly maintain this alignment, the user may fix the cover 130 to the main body 110 through the fixing unit 170 .

The user now operates the light irradiator LE to direct the irradiation light to the fiducial mark 139 along the light path LP. Then, the irradiated light is transmitted through the test object 150 and received as transmitted light by the light sensing unit 210 . The photodetector 210 converts transmitted light into data and transmits it to an external computing device.

The external computing device calculates information for determining the radiation dose of the light irradiator LE based on the received data. The user may determine the radiation dose for a specific tooth among the user's teeth using the corresponding light irradiation device LE based on the corresponding information, and set the light irradiation device LE based on this.

The oral cavity imaging sensor storage device and the oral cavity imaging sensor assembly having the same as described above are not limited to the configuration and operation method of the embodiments described above. Each of the above embodiments may be combined so that various modifications can be made.

100: oral imaging sensor storage device 110: main body
120: support 130: cover
150: test object 170: fixed unit
200: oral imaging sensor 210: light detection unit
250: cable

Claims (12)

A main body having an accommodation space in which an intraoral imaging sensor is accommodated;
a cover coupled to the main body to cover the accommodation space;
A test installed on the cover and disposed before the oral cavity imaging sensor so that irradiation light emitted from the light irradiation device in a state in which the cover covers the accommodation space is transmitted while traveling to the oral cavity imaging sensor located in the accommodation space. subject; and
An oral imaging sensor housing device comprising a fixing unit configured to secure the cover relative to the body, such that the test subject remains aligned with the intraoral imaging sensor along an optical path.
According to claim 1,
When the oral imaging sensor is composed of a light sensing unit for receiving the transmitted light transmitted through the test object, and a cable for transmitting data converted by detecting the transmitted light in the light sensing unit to an external computing device,
the body,
floor;
a side wall protruding from the bottom to define the receiving space in an open top; and
A oral imaging sensor storage device comprising a passage hole opened in the side wall and providing a passage through which the cable extends to the external computing device.
According to claim 2,
Further comprising a support accommodated in the accommodation space,
The support is
a first seating groove in which the light sensing unit is seated;
a second seating groove communicating with the first seating groove and receiving the cable; and
The oral imaging sensor storage device comprising a third seating groove communicating the second seating groove and the passage hole.
According to claim 1,
the cover,
Including an outer skin and an inner skin that are combined with each other,
The test subject,
Between the outer shell and the inner shell, disposed to be parallel to the oral cavity imaging sensor, the oral cavity imaging sensor storage device.
According to claim 1,
the cover,
Including a fiducial mark indicating an area corresponding to the test object in a direction along the light path, oral imaging sensor housing device.
According to claim 1
The test subject,
An oral imaging sensor housing device comprising a plurality of target regions having different thicknesses.
An oral imaging sensor storage device for accommodating an oral imaging sensor having a light sensing unit for receiving light and a cable for transmitting data generated by light detected by the light sensing unit to an external computing device,
a main body having an accommodation space in which the intraoral imaging sensor is accommodated;
a cover coupled to the main body to cover the accommodation space; and
It is installed on the cover and includes a test object disposed in front of the oral cavity imaging sensor so that the irradiation light emitted from the light irradiation device passes through while traveling to the oral cavity imaging sensor,
the body,
In a state in which the cover covers the main body, the cable extends to the outside of the main body to send the transmitted light transmitted through the test object to the external computing device by the light sensing unit and transmits converted data to the external computing device. Further comprising a through hole allowing to be connected to the device, oral imaging sensor storage device.
According to claim 7,
the cover,
Including an outer skin and an inner skin that are combined with each other,
The test subject,
An oral imaging sensor housing device disposed between the outer shell and the inner skin and arranged parallel to the intraoral imaging sensor.
According to claim 7,
The oral imaging sensor housing device further comprises a fixing unit for fixing the cover to the main body so that the test subject remains aligned along a light path with respect to the intraoral imaging sensor.
an oral imaging sensor having a photodetector for receiving light and a cable for transmitting data sensed by the photodetector to an external computing device; and
Including an oral imaging sensor storage device accommodating the intraoral imaging sensor,
The oral imaging sensor storage device,
a case body having an accommodation space in which the intraoral imaging sensor is seated; and
A test object installed in the case body and disposed in front of the oral cavity imaging sensor so that irradiation light emitted from the light irradiation device passes through the oral cavity imaging sensor,
The test object is used for calculating information for determining the dose of the light irradiation device based on data obtained by the light sensing unit receiving and converting the transmitted light transmitted through the test object by the external computing device, oral imaging sensor assembly.
According to claim 10,
The case body,
a main body having an accommodation space in which the intraoral imaging sensor is accommodated; and
And a cover coupled to the main body to cover the accommodation space,
the cover,
Including an outer skin and an inner skin that are combined with each other,
The test subject,
An oral imaging sensor assembly disposed between the outer skin and the inner skin and arranged in parallel with the oral imaging sensor.
A main body having an accommodation space in which an intraoral imaging sensor is accommodated;
a cover coupled to the main body to cover the accommodation space; and
It is installed on the cover and includes a test object disposed in front of the oral cavity imaging sensor so that the irradiation light emitted from the light irradiation device passes through while traveling to the oral cavity imaging sensor,
The test subject,
It is installed on the cover and is arranged in parallel with the oral imaging sensor,
When the intraoral imaging sensor is composed of a light sensing unit for receiving the transmitted light transmitted through the test object, and a cable for transmitting the data converted by detecting the transmitted light in the light sensing unit to an external computing device, the test The object is used for calculating information for determining the dose of the light irradiation device based on the data obtained by the light sensing unit receiving and converting the transmitted light transmitted through the test object by the external computing device. device.

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