CN210246937U - 3D image capturing equipment with observation mirror - Google Patents

Abstract

A3D image capturing device for a viewing mirror is characterized in that a tube body is nested at the front end of a bougie of the viewing mirror, a plug connector for being plugged in a control circuit is arranged at the rear end of the bougie, at least one lens, a light emitting assembly juxtaposed with the lens and an infrared sensing piece are arranged at the end of the tube body. When the observation mirror is used, the light-emitting component can be used for lighting, the lens can be used for capturing images of organs, the infrared sensing piece can be used for drawing a 3D image for comparing the images of the lens in a computer through the refraction time, the surface temperature of the organs can be monitored, and the abnormality of the organs can be judged. The lens, the juxtaposed light-emitting component and the infrared sensing component are fixed or connected with a circuit board provided with a control component through wires, and the circuit board is arranged in the outer tube body or the plug connector.

Description

3D image capturing equipment with observation mirror

Technical Field

The utility model relates to a sight glass 3D image capture equipment indicates especially an image that can supply to pick up the organ, and can supply to draw the 3D picture of comparing the camera lens image to and supply monitoring organ surface temperature, and then can do benefit to the sight glass 3D image capture equipment of judging the organ anomaly.

Background

The common trachea cannula is divided into functions of an endoscope and an observation mirror, wherein the endoscope can be used for observing the state of human organs and simultaneously has the operation functions of blowing, flushing, cutting or electric heating and the like. The observation mirror is only used for observation and does not have the operation function like an endoscope. The prior observation mirror is provided with a transparent endotracheal tube made of soft material, a flexible bougie is inserted in the endotracheal tube, wherein, the front end of the bougie is provided with a tube body, components such as a lens, an optical component and the like are arranged in the tube body, the rear end is provided with a plug connector for being inserted in a hand piece provided with a transmission circuit, the endotracheal tube and the bougie are inserted in a patient mouth when in use, the camera lens captures an image of an organ after the light component illuminates the organ, then the image signal is transmitted to the plug connector arranged at the rear end of the bougie, the transmission circuit of the hand piece inserted by the plug connector transmits an analog or digital image signal to a display device such as a flat computer for viewing, and the like

The lens of the conventional observation mirror is usually designed in a single way, so that the function of the observation mirror can only capture the image of an organ, and the image display at the rear end is difficult to present an exact position and a thin abnormal state, such as: the conception condition of uterus, the position of the fertilized egg or whether the fertilized egg has other objects, etc., and when the lens is moved, the distance between the lens and the organ is difficult to judge, so that the lens is often moved too far to influence the interpretation, and the situation is actually a long-term defect of the observation mirror. In view of the above, through continuous research and experiments, an observation mirror 3D image capturing device is designed to facilitate the judgment of organ abnormality.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main objective is providing a sight glass 3D image capture equipment promptly, makes the sight glass except that the image that can supply to pick the organ, and can supply to draw the 3D picture of comparing the camera lens image to and can supply monitoring organ surface temperature, and then can do benefit to the anomaly of judging the organ.

In the foregoing 3D image capturing device with a viewing mirror, a tube is nested at the front end of the bougie of the viewing mirror, a connector for connecting to a control circuit is disposed at the rear end of the bougie, and at least one lens, a light emitting module juxtaposed to the lens, and an infrared sensing module are disposed at the end of the tube. When the observation mirror is used, the light-emitting component can be used for lighting, the lens can be used for capturing images of organs, the infrared sensing piece can be used for drawing a 3D image for comparing the images of the lens in a computer through the refraction time, the surface temperature of the organs can be monitored, and the abnormality of the organs can be judged.

In the foregoing viewing mirror 3D image capturing apparatus, the two lenses and the juxtaposed light emitting component are welded and fixed to a control circuit board provided with an electronic component, and the control circuit board is disposed inside the outer tube body.

In the foregoing viewing mirror 3D image capturing apparatus, the two lenses and the juxtaposed light emitting device are connected to a control circuit board provided with an electronic device, and the control circuit board is disposed inside the connector.

In the foregoing viewing mirror 3D image capturing apparatus, the light emitting component is a high brightness Light Emitting Diode (LED).

In the foregoing viewing mirror 3D image capturing apparatus, the infrared sensing element is a sensing element capable of emitting and receiving invisible infrared rays.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a structural diagram of a first embodiment of the present invention.

Fig. 3 is a usage state diagram of the first embodiment of the present invention.

Fig. 4 is a structural view of a second embodiment of the present invention.

Fig. 5 is a structural view of a third embodiment of the present invention.

Fig. 6 is a structural view of a fourth embodiment of the present invention.

Description of the reference numerals

1. Endotracheal tube

2. Bougie

21. Pipe body

3. Plug-in connector

4. Hand-held piece

41. Transmission circuit

42. Display device

5. Lens barrel

6. Light emitting assembly

7. Infrared sensing piece

8. Control circuit board

81. Control assembly

82. Conducting wire

9. A circuit board.

Detailed Description

Please refer to fig. 1 and fig. 2, which are a perspective view and a structural diagram of the first embodiment of the present invention. As shown in the figures, the present invention provides a transparent endotracheal tube 1 made of soft material, and a flexible bougie 2 is inserted into the endotracheal tube 1 as the existing observation mirror. The front end of the bougie 2 is nested with a tube 21, an image capturing unit composed of components such as a lens and a light emitting component is arranged in the tube 21, and the rear end of the bougie 2 is provided with a plug connector 3 for being plugged in a handheld piece 4 provided with a transmission circuit 41. When the endotracheal tube 1 and the bougie 2 are inserted into a patient's mouth, the image of an organ is captured by the lens after being illuminated by the image capturing unit light assembly, and an analog or digital image signal is transmitted to a display device 42 such as a tablet computer through a transmission circuit 41, so that the state of the organ of the human body can be observed.

The end of the tube 21 is provided with at least one lens 5, and at least one light emitting component 6 and infrared sensing component 7 juxtaposed with the lens 5, the light emitting component 6 and the infrared sensing component 7 are at proper intervals, so that the lens 5, the light emitting component 6 and the infrared sensing component 7 are respectively exposed from the end of the tube 21. In this embodiment, the lens 5, the light emitting element 6 and the infrared sensor 7 are soldered to a control circuit board 8 having an electronic component 81, the control circuit board 8 is fixed inside the tube 21 and connected to the connector 3 by a wire 82; the light emitting element 7 is a high-brightness Light Emitting Diode (LED), and the infrared sensor 7 is a sensor of invisible light and infrared light.

Through the above-mentioned components combination, when the observation mirror is used, the light-emitting component 6 arranged on the front end tube body 21 of the bougie 2 can be used for lighting, the lens 5 can be used for capturing the organ image, and the organ image can be displayed on the display device 42 such as the aforementioned tablet computer, so as to observe the state of the human organ. The infrared sensor 7 can draw a 3D image for comparing the lens image and monitor the organ surface temperature on the computer or other display device 42 through the refraction time, which is further advantageous for determining the abnormality of the organ (collecting the infrared energy radiated from the object to be measured and focusing the infrared energy on the detector, the detector converts the infrared energy into an electrical signal, and the electrical signal is amplified and displayed as a temperature value).

The utility model discloses use and observe uterus and fertilized egg as the example, the bodily form is calculated out to the refraction time (distance) of accessible infrared ray sensing piece 7, draws the 3D picture by display device 42 (panel computer) such as computer to the image that the camera lens 5 was picked up is compared to the confession, and then can learn the correct position of fertilized egg. The infrared sensing element 7 can also monitor the surface temperature of the uterus to know the pregnancy status of the uterus (working principle of infrared temperature measurement, namely, all objects can emit infrared energy, the molecules of the objects are more active when the objects are heated, and the emitted infrared energy is more, the infrared sensing element 7 can collect the infrared energy radiated by the objects and gather the energy, and further convert the energy into electric signals, and the electric signals are amplified and displayed as temperature readings), and corresponding observation is carried out on the images captured by the lens 5 according to whether the surface temperature is consistent (3D images are carried out on the display device 42 and the images captured by the lens 5 are displayed for corresponding observation), so that whether other abnormal objects exist except fertilized eggs can be further judged.

Another objective of the present invention is to calculate the corresponding distance between the lens 5 and the organ through the refraction time of the infrared sensing element 7, so that the lens 5 will not exceed the organ to be observed (e.g. the distance between the lens 5 and the trachea, the distance between the lens 5 and the lung, or the distance between the deep mouth and the cavity) during the operation of the observation mirror, thereby facilitating the operation, use and interpretation of the observation mirror.

Please refer to fig. 3, which is a state diagram illustrating a first embodiment of the present invention. Referring to fig. 1, when capturing the image of the organ, the lens 5 is disposed at the end of the tube 21 to capture the image of the organ. The infrared sensing element 7 can emit invisible infrared rays, and receive the refracted signal after the invisible infrared rays are refracted by the contacting organ. So that the organ shape can be deduced using the refraction time.

Please refer to fig. 4, which is a structural diagram of a second embodiment of the present invention. As shown in the figures, the second embodiment of the present invention can embed the lens 5, the light emitting component 6 and the infrared sensing element 7 in the tube 21 (end) fixed to the bougie 2, so that the lens 5, the light emitting component 6 and the infrared sensing element 7 are exposed from the end of the tube 21, and the control circuit board 8 is disposed inside the connector 3, wherein the lens 5, the light emitting component 6, the infrared sensing element 7 and the control circuit board 8 are connected to each other via the wires 82, and the control circuit board 8 and the connector 3 are connected to each other via the wires.

Please refer to fig. 5, which is a structural diagram of a third embodiment of the present invention. As shown in the figures, the third embodiment of the present invention can fix the lens 5, the light emitting component 6 and the infrared sensing component 7 to a circuit board 9 by welding, fix the circuit board 9 inside the tube 21 of the bougie 2, make the lens 5, the light emitting component 6 and the infrared sensing component 7 exposed from the end of the tube 21, and locate the control circuit board 8 inside the connector clip 3, connect the circuit board 9 and the control circuit board 8, and connect the control circuit board 8 and the connector clip 3 with the wire 82.

Please refer to fig. 6, which is a structural diagram of a fourth embodiment of the present invention. As shown in the drawings, the fourth embodiment of the present invention can solder-fix the lens 5, the light emitting component 6 and the infrared sensing element 7 to a circuit board 9, combine the circuit board 9 with the control circuit board 8 having the control electronic component 81, so that the lens 5, the light emitting component 6 and the infrared sensing element 7 are exposed from the end of the tube 21, wherein the circuit board 9 is connected to the control circuit board 8 at an angle of 90 ° (the circuit board 9 is vertical, the control circuit board 8 is horizontal, and both are inverted T-shaped after being combined), and the control circuit board 8 is connected to the connector 3 by a wire 82.

To sum up, the utility model discloses in the body of sight glass bougie, be equipped with two at least camera lenses and two light-emitting component, make this camera lens and light-emitting component be suitable interval, the control circuit board of body inside or plug connector inside is located in the cooperation, constitutes sight glass 3D image capture equipment, makes the sight glass except can supplying the image of picking the organ, and can supply to draw the 3D picture of comparing the camera lens image to and can supply monitoring organ surface temperature, and then can do benefit to the anomaly of judging the organ.

Although the present invention has been described with reference to the above preferred embodiments, it is not intended to limit the scope of the present invention, and various changes and modifications relative to the above embodiments may be made by those skilled in the art without departing from the spirit and scope of the present invention.

Claims (7)

1. The utility model provides a sight glass 3D image capture equipment, be equipped with a soft material and be the endotracheal tube of transparent form, plant a flexible bougie in this endotracheal tube, the front end nestification of this bougie has a body, be equipped with image acquisition unit in the body, the bougie rear end is equipped with a plug connector, for peg graft in a handheld piece that is equipped with transmission circuit, when using, insert the endotracheal tube in the disease mouth with the bougie, the image of organ is captured through image acquisition unit, image signal transmission to panel computer display device with simulation or digit through transmission circuit, for seeing human organ state, a serial communication port, the utility model is characterized in that:

the image capturing unit of the tube body is provided with at least one lens, at least one light-emitting component and an infrared sensing component, wherein the light-emitting component and the infrared sensing component are juxtaposed with the lens, the light-emitting component and the infrared sensing component are in proper intervals and are respectively connected with a control circuit board, and the control circuit board is connected with a plug connector.

2. The viewer 3D image capturing apparatus of claim 1, wherein the lens and light emitting device and the infrared sensor are soldered to a control circuit board, and the control circuit board is fixed inside the tube and connected to the connector by a wire.

3. The viewer 3D image capturing apparatus of claim 1, wherein the lens and the light emitting element and the infrared sensor are embedded and fixed in the tube, and the control circuit board is disposed inside the connector, and the lens and the light emitting element are connected to the control circuit board and the control circuit board is connected to the connector by wires.

4. The viewer 3D image capturing apparatus of claim 1, wherein the lens and light emitting elements and the ir sensing element are soldered to a circuit board, the circuit board is fixed inside the tube, the control circuit board is disposed inside the connector, the circuit board is connected to the control circuit board, and the control circuit board is connected to the connector by wires.

5. The viewer 3D image capturing apparatus of claim 1, wherein the lens and light emitting device and the infrared sensor are soldered to a circuit board, the circuit board is combined with the control circuit board at vertical and horizontal angles, and the control circuit board is connected to the connector by a wire.

6. The viewer 3D image capture device of claim 1, wherein the light emitting element is a high brightness light emitting diode.

7. The viewer 3D image capturing apparatus of claim 1, wherein the infrared sensor is a sensor that can emit and receive invisible infrared light.

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