CN217504988U - Portable infrared thermal image detector - Google Patents

Portable infrared thermal image detector Download PDF

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Publication number
CN217504988U
CN217504988U CN202122754076.1U CN202122754076U CN217504988U CN 217504988 U CN217504988 U CN 217504988U CN 202122754076 U CN202122754076 U CN 202122754076U CN 217504988 U CN217504988 U CN 217504988U
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box body
imaging head
infrared
infrared imaging
portable
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CN202122754076.1U
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张巍
邓俊杰
姚孝清
孙莉
唐亮
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Wuhan Guangzhi Technology Co ltd
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Wuhan Guangzhi Technology Co ltd
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Abstract

The utility model discloses a portable infrared thermal image detector, which comprises an image display screen and an infrared imaging head; the method is characterized in that: the image display screen and the infrared imaging head are integrally arranged into a portable box body, the image display screen forms a panel of the box body, the infrared imaging head is arranged in the box body and is electrically connected with the image display screen through a controller in the box body, and a lens surface of the infrared imaging head faces towards a detection target. The utility model discloses an organic whole sets up, portable, practice thrift space, convenient operation, and techniques such as integrated infrared technique, medical imaging analysis and 5G connect cloud platform through the network port, can be based on a large amount of cases correct analysis data to issuing the diagnosis report after carrying out the analysis to infrared chart.

Description

Portable infrared thermal image detector
Technical Field
The utility model relates to a novel medical infrared thermal imagery detector belongs to medical infrared thermal imagery technical field.
Background
The human body is a biological heating body, and different organs of the human body have different temperatures to form different thermal fields. Normal bodies have normal heat maps, and abnormal bodies present abnormal heat maps. Comparing the difference between the two, diagnosing by combining clinic and judging the nature and degree of the body disease.
According to the biological characteristics, the medical thermal infrared imager can convert infrared light radiated by a human body into a visible image reflecting a thermal field of the human body, and the visible image is displayed in a color thermal image form, so that a doctor can conveniently see and judge.
The existing infrared thermal image detector is large in size and inconvenient to carry, and the image display and the infrared lens are arranged at two positions and occupy space. In addition, the lens of the existing thermal infrared imager detector needs to be driven by a motor for adjustment, so that the operation is complex and energy is consumed.
SUMMERY OF THE UTILITY MODEL
The to-be-solved technical problem of the utility model is to provide a medical infrared detector of integral type convenient to carry, practice thrift space, convenient operation.
Meanwhile, the infrared technology, the medical imaging analysis technology, the 5G technology and the like are integrated, the cloud platform is connected through a network port, data can be correctly analyzed based on a large number of cases, and a diagnosis report can be issued after the infrared thermograph is analyzed.
The utility model discloses a solve the technical scheme that above-mentioned technical problem adopted and be:
a portable infrared thermal image detector comprises an image display screen and an infrared imaging head; the method is characterized in that:
the image display screen and the infrared imaging head are integrally arranged into a portable box body, the image display screen forms a panel of the box body, the infrared imaging head is arranged in the box body and is electrically connected with the image display screen through a controller in the box body, and a lens surface of the infrared imaging head faces towards a detection target.
In the technical scheme, the infrared imaging head is arranged between the back of the image display screen and the box body back plate, and the box body back plate is provided with the lens hole matched with the lens surface view finding range.
In the technical scheme, the infrared imaging head is movably arranged in the box body in a manner of adjusting the pitching angle.
Among the above-mentioned technical scheme, infrared imaging head sets up in the box through the mode activity of manual adjustable every single move angle.
In the technical scheme, the pitching angle of the infrared imaging head is manually adjusted through a rotation-rotation conversion mechanism arranged on the box body; or the pitch angle of the infrared imaging head is adjusted through a linear-rotary conversion mechanism manual belt arranged on the box body.
In the technical scheme, a manual knob is arranged on one side part of the box body; the root of the infrared imaging head is hinged to the top of the box body, and a synchronous belt wheel is fixed at the lens end; the knob and a synchronous belt wheel at the lens end of the infrared imaging head form a rotation-rotation conversion transmission pair through the synchronous belt wheel and the synchronous belt; the axis of the knob is parallel to the axis of the synchronous belt wheel on the infrared imaging head, so that the infrared imaging head performs pitch-over action under the manual rotation action of the knob; or the root of the infrared imaging head is hinged to the top of the box body, and a swing rod is fixed to the lens end; the manual knob is hinged with the swing rod through another swing rod mechanism to form a rotation-rotation conversion kinematic pair, and the infrared imaging head is bent over to move under the manual rotation effect of the knob through the swing rod kinematic pair.
In the technical scheme, a horizontal sliding chute and a matched sliding block are arranged on one side part of the box body, the root part of the infrared imaging head is hinged to the top of the box body, a rotating wheel is fixed at the end of a lens end, the sliding block is hinged to one end of a connecting rod, and the other end of the connecting rod is hinged to the rotating wheel to form the linear-rotation conversion mechanism; the sliding block drives the connecting rod to move through horizontal motion to drive the rotating wheel to rotate, and the lens fixed on the rotating wheel is driven to perform pitching motion.
In the technical scheme, the knob or the sliding block is provided with grooves convenient to control; or the knob is set to be of a plum petal-shaped structure so as to be convenient to control.
Among the above-mentioned technical scheme, the top of box sets up an opening as portable handle, and the terminal surface sets up the spill or the line structure of being convenient for to hold in the handle.
In the technical scheme, the box body is provided with a power supply hole or a battery jar, a network communication port, a data port and a heat dissipation hole. The box body is internally provided with a heat dissipation system comprising a fan corresponding to the heat dissipation holes.
The preferred network communication port is a 5G port, and the data port is compatible with at least a USB port.
The controller in the box body comprises a CPU, a 5G module, a heat dissipation system, a power management system and an AI medical imaging module. The AI medical imaging module is capable of analyzing conditions at different locations based on the human body thermal map. Meanwhile, with the increase of inquiry cases, the inquiry cases can be transmitted to a cloud platform to accumulate more heat maps and corresponding cases by combining a 5G technology, so that the diagnosis accuracy of various diseases is improved.
The power management system can reasonably distribute electric energy for use, and the equipment can work for a long time.
The utility model discloses a theory of operation does:
the inspection tester is an integrated machine, is convenient to carry and is easy to operate. And the requirement on the operating environment is not high. When infrared thermography inspection is carried out, a power supply is switched on (or a self-contained battery is used), and a computer is started.
After the system is stable in operation, firstly, the human body is shot with an infrared thermal image. And adjusting the angle of the infrared lens according to the distance between the person and the detector, and shooting a complete human body heat map. Preferably, the examiner stands 1-5 meters in front of the detector, adjusts the pitch angle of the infrared lens, aims at the human body or the body part of the human body to be examined, and shoots the infrared chart.
And then transmitting the heat map to a CPU (central processing unit) of a controller in the box body, or simultaneously transmitting the heat map to a cloud platform through a network, wherein the heat map is displayed on an image display screen, and meanwhile, the cloud platform carries out big data analysis on the received heat map, marks and diagnoses the abnormal temperature area of the human body, and finally provides a diagnosis report. Meanwhile, the cloud platform is a learning process through the accumulation of a plurality of cases, and the diagnosis accuracy of the diseases is continuously improved.
The inspection tester with the heat dissipation system can effectively reduce the temperature of the infrared lens and ensure the temperature resolution of the lens.
Compared with the prior art, the beneficial effects of the utility model are that:
1. the infrared technology, the medical imaging analysis, the 5G technology and the like are integrated, an integrated structure is adopted, the appearance is close to the size of a tablet personal computer, an industrial-level high-precision detection device is truly portable and integrated, the existing connecting line between assembling devices is not needed, the placing problems of various components are not taken into consideration, all functions are integrated in a box body, the device is small and exquisite, the occupied space is not occupied, the operation is simple, and the carrying and the use are convenient.
2. The infrared lens adopts a simple, easy-to-operate and energy-saving adjusting mechanism, and is convenient for shooting the whole body or local infrared chart of the human body.
3. The thermal imager has a good heat dissipation system, avoids the influence of temperature on the thermal imager, and ensures the temperature sensitivity of the thermal imager.
4. And a power management system is configured, so that the detector can work normally for a longer time.
5. The cloud platform is connected through the network port, so that data can be correctly analyzed based on a large number of cases, and a diagnosis report can be issued after the infrared chart is analyzed.
Drawings
The invention will be further explained with reference to the drawings and examples, wherein:
FIG. 1 is a schematic view of a three-dimensional structure of a portable infrared thermal image detector in embodiment 1 of the present invention;
fig. 2 is a back schematic view of the portable infrared thermal image detector of embodiment 1 of the present invention.
Fig. 3 is a schematic diagram of a side power supply and a network interface according to embodiment 1 of the present invention.
Fig. 4 is a schematic front structural view (display screen located surface) of the portable infrared thermal image detector of embodiment 2 of the present invention.
Fig. 5 is a schematic diagram of the back internal structure of the portable infrared thermal image detector according to embodiment 2 of the present invention (after the back plate is removed).
Fig. 6 is a schematic side internal structure view of the portable infrared thermal image detector of embodiment 2 of the present invention.
Fig. 7 is a schematic side internal structure diagram of the portable infrared thermal image detector of embodiment 3 of the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.
Example 1:
as shown in fig. 1-3, according to the utility model discloses a portable thermal infrared image detector is as shown in fig. 1, and image display screen 6 and infrared imaging head 10 an organic whole set to integrated portable box 1, image display screen 6 constitutes the panel of box, and infrared imaging head 10 covers in the box and is connected through being connected between controller in the box and the image display screen 6 by backplate 11, and the camera lens face of infrared imaging head 6 sets up towards the detection target.
The infrared imaging head 10 is arranged between the back of the image display screen 6 and the box body back plate 11, and the box body back plate 11 is provided with a lens hole 110 matched with the lens surface view finding range.
An opening is formed in the top of the box body 1 to form a handle 7, and concave groove grains are arranged at the contact part of the handle 7 and a hand to facilitate holding.
A power supply connector 9, a network interface 8, a heat dissipation hole 3 and a data interface 4 are arranged on the side part of the box body 1, a power supply button 5 can be communicated with an internal battery bin and is also communicated with the power supply connector 9, and switching distribution is carried out through a power supply management system with a built-in controller. The heat dissipation holes 3 correspond to a built-in heat dissipation system, which at least includes a fan 31. The fan 31 is connected to the built-in controller.
A manual adjusting knob 2 is arranged on one side part of the box body 1, and the pitching direction of the infrared imaging head 10 can be adjusted through the manual adjusting knob 2, so that the infrared imaging head is suitable for different human body shooting positions. The manual knob 2 is provided with grains for convenient regulation and control.
Example 2:
as shown in fig. 4 to 6, the difference from embodiment 1 is that the knob 22 is changed from a cylindrical knob to a quincunx knob. The operation and control are convenient. The controller and the interface circuits are integrated on the circuit board 111 inside the housing back plate 11.
As shown in fig. 6, a manual knob 22 is provided on one of the side portions of the case 1; the root part of the infrared imaging head 10 is hinged inside the top part of the box body 1, and a synchronous belt wheel 222 is fixed at the lens end; the manual knob 22 and a synchronous pulley 222 at the lens end of the infrared imaging head form a rotation-rotation conversion transmission pair through a synchronous pulley and a synchronous belt 223 which are coaxially arranged; the axis of the manual knob 22 is parallel to the axis of the synchronous pulley 222 on the infrared imaging head, so that the infrared imaging head tilts down under the rotation of the manual knob 22.
Other conventional mechanisms not shown may be employed as the rotary rotation mechanism. If the root of the infrared imaging head is hinged to the top of the box body 1, and a swing rod is fixed at the lens end; the manual knob 22 is hinged to the swing rod through another swing rod mechanism to form a rotation-rotation conversion kinematic pair, and the knob 22 enables the infrared imaging head 10 to tilt under the manual rotation effect of the knob through the swing rod kinematic pair. One skilled in the art can select an appropriate adjustment mechanism as desired.
Of course, the utility model provides a camera lens guiding mechanism also can adopt conventional automatically controlled mode, sets up the band pulley that gear and camera lens on the motor output shaft and constitutes synchronous pulley, perhaps the rotatory direct control every single move action of motor shaft, this all belongs to the technical staff in this field and follows the utility model discloses obtain the implementation structure that the inspiration can be realized.
Example 3: as shown in fig. 7, this embodiment is different from embodiments 1 and 2 in that the rotation-rotation converting mechanism of the lens tilting action of the infrared imaging head 10 is changed to a horizontal-rotation converting mechanism.
Fig. 7 shows an implementation structure in which a knob adjusts the tilt of infrared imaging head 10 through a horizontal-rotation conversion mechanism. This structure is also applicable to embodiment 1. In fig. 6, a horizontal sliding groove and a matched sliding block 222 are arranged on one side of the box body 1, the root of the infrared imaging head 10 is hinged on the top of the box body 1, a rotating wheel 2223 is fixed at the lens end, the sliding block 222 is hinged on one end of a connecting rod 2221, and the other end of the connecting rod 2221 is hinged on the rotating wheel 2223 to form the linear-rotary conversion mechanism; the slider 222 drives the connecting rod 2221 to move integrally and rotate by a horizontal sliding motion (both left and right sliding) along the slider to drive the rotating wheel 2223 to rotate, so as to drive the lens tilting motion of the infrared imaging head 10 fixed on the rotating wheel 2223.
In the above embodiments, the controller in the box 1 includes a CPU, a 5G module, a heat dissipation system, a power management system, and an AI medical imaging module. The AI medical imaging module is capable of analyzing conditions at different locations based on the human body thermal map. Meanwhile, with the increase of the cases for inquiry, the heat map and the corresponding cases can be transmitted to a cloud platform to accumulate more heat maps and corresponding cases by combining a 5G technology, so that the diagnosis accuracy rate of various diseases is improved.
In a preferred embodiment, grooves which are convenient to operate and control are arranged on the knob or the sliding block; or the knob is arranged in a plum petal-shaped structure as in embodiment 2 to be convenient for operation.
The preferred network communication port is a 5G port, and the data port is compatible with at least a USB port.
The utility model discloses a theory of operation does:
when the infrared thermography inspection is needed, a power supply is switched on (or a self-contained battery is used), and a computer is started.
After the system is stably operated, an inspector preferably stands 1-5 meters in front of the detector, adjusts the pitch angle of the infrared lens, aims at the human body or the body part of the human body to be inspected, and shoots an infrared thermal image.
And then transmitting the heat map to a CPU (central processing unit) of a controller in the box body, or simultaneously transmitting the heat map to a cloud platform through a network, wherein the heat map is displayed on an image display screen, and meanwhile, the cloud platform carries out big data analysis on the received heat map, marks and diagnoses the abnormal temperature area of the human body, and finally provides a diagnosis report. Meanwhile, the cloud platform is a learning process through the accumulation of a plurality of cases, and the diagnosis accuracy of the diseases is continuously improved.
Compared with the prior art, the beneficial effects of the utility model are that:
1. the infrared technology, the medical imaging analysis, the 5G technology and the like are integrated, an integrated structure is adopted, the appearance is close to the size of a tablet personal computer, an industrial-level high-precision detection device is truly portable, the equipment is small and exquisite, the occupied space is not occupied, the operation is simple, and the carrying and the use are convenient.
2. The infrared lens adopts a simple, easy-to-operate and energy-saving adjusting mechanism, and is convenient for shooting the whole body or local infrared chart of the human body.
3. The thermal imager has a good heat dissipation system, avoids the influence of temperature on the thermal imager, and ensures the temperature sensitivity of the thermal imager.
4. And a power management system is configured, so that the detector can work normally for a longer time.
5. The cloud platform is connected through the network port, so that data can be correctly analyzed based on a large number of cases, and a diagnosis report can be issued after the infrared chart is analyzed.
It will be understood that modifications and variations can be resorted to by those skilled in the art, and that all such modifications and variations are intended to be included within the scope of the invention as claimed.

Claims (9)

1. A portable infrared thermal image detector comprises an image display screen and an infrared imaging head; the method is characterized in that: the image display screen and the infrared imaging head are integrally arranged into a portable box body, the image display screen forms a panel of the box body, the infrared imaging head is arranged in the box body and is electrically connected with the image display screen through a controller in the box body, and a lens surface of the infrared imaging head faces a detection target; the infrared imaging head is arranged between the back of the image display screen and the box body back plate, and the box body back plate is provided with a lens hole matched with the lens surface view finding range.
2. The portable infrared thermal image detector of claim 1, wherein: the infrared imaging head is movably arranged in the box body in a manner of adjusting the pitching angle.
3. The portable infrared thermographic inspection instrument of claim 1, wherein: the infrared imaging head is movably arranged in the box body in a manner of manually adjusting the pitching angle.
4. The portable infrared thermographic inspection instrument of claim 1, wherein: the pitching angle of the infrared imaging head is manually adjusted through a rotation-rotation conversion mechanism arranged on the box body; or the pitch angle of the infrared imaging head is adjusted through a linear-rotary conversion mechanism manual belt arranged on the box body.
5. The portable infrared thermographic inspection instrument of claim 4, wherein: a manual knob is arranged on one side of the box body; the root of the infrared imaging head is hinged to the top of the box body, and a synchronous belt wheel is fixed at the lens end; the knob and a synchronous belt wheel at the lens end of the infrared imaging head form a rotation-rotation conversion transmission pair through the synchronous belt wheel and the synchronous belt; the axis of the knob is parallel to the axis of the synchronous belt wheel on the infrared imaging head, so that the infrared imaging head performs pitch-over action under the manual rotation action of the knob; or the root of the infrared imaging head is hinged to the top of the box body, and a swing rod is fixed to the lens end; the manual knob is hinged with the swing rod through another swing rod mechanism to form a rotation-rotation conversion kinematic pair, and the infrared imaging head is bent over to move under the manual rotation effect of the knob through the swing rod kinematic pair.
6. The portable infrared thermographic inspection instrument of claim 4, wherein: one side part of the box body is provided with a horizontal sliding chute and a matched sliding block, the root part of the infrared imaging head is hinged at the top part of the box body, a rotating wheel is fixed at the end of a lens end, the sliding block is hinged at one end of a connecting rod, and the other end of the connecting rod is hinged with the rotating wheel to form the linear-rotation conversion mechanism; the sliding block drives the connecting rod to move through horizontal motion to drive the rotating wheel to rotate, and the lens fixed on the rotating wheel is driven to perform pitching motion.
7. A portable infrared thermographic inspection instrument according to claim 5 or 6, in which: the knob or the sliding block is provided with grooves convenient for control; or the knob is set to be of a plum petal-shaped structure so as to be convenient to control.
8. The portable infrared thermographic inspection instrument of claim 1, wherein: an opening is arranged at the top of the box body and used as a portable handle, and a concave or grain structure convenient to hold is arranged on the inner end surface of the handle.
9. The portable infrared thermographic inspection instrument of claim 1, wherein: the box body is provided with a power supply hole or a battery jar, a network communication port, a data port and a heat dissipation hole.
CN202122754076.1U 2021-11-11 2021-11-11 Portable infrared thermal image detector Active CN217504988U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202122754076.1U CN217504988U (en) 2021-11-11 2021-11-11 Portable infrared thermal image detector

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202122754076.1U CN217504988U (en) 2021-11-11 2021-11-11 Portable infrared thermal image detector

Publications (1)

Publication Number Publication Date
CN217504988U true CN217504988U (en) 2022-09-27

Family

ID=83336950

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202122754076.1U Active CN217504988U (en) 2021-11-11 2021-11-11 Portable infrared thermal image detector

Country Status (1)

Country Link
CN (1) CN217504988U (en)

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