CN219661651U - Heat radiator for endoscope wireless image transmission structure - Google Patents

Abstract

The utility model discloses a heat dissipation device of an endoscope wireless line transmission structure, and particularly relates to the field of endoscopes. According to the utility model, through the relationship among the vapor chamber, the first shell, the blind holes and the metal fins, when the device is used in the later period, the metal fins can radiate heat inside the first shell, and the endoscope elements inside the first shell can radiate heat by matching with the blind holes. Meanwhile, the device adopts a mode of clamping the notch at the front end of the sleeve layer with the buckle to mount the first shell, and the notch at the front end of the sleeve layer is controlled to be separated from the buckle by rotating the first shell to perform disassembly type heat dissipation or rapid replacement of the shell.

Description

Heat radiator for endoscope wireless image transmission structure

Technical Field

The utility model relates to the field of endoscopes, in particular to a heat dissipation device of a wireless image transmission structure of an endoscope.

Background

The endoscope is an optical instrument which is sent into the body from the outside through the natural cavity of the human body to check the internal diseases, can directly observe the pathological changes of the internal cavity of the viscera, determine the position and the range of the pathological changes, can take pictures, biopsies or brush sheets, greatly improves the diagnosis accuracy of cancers and can carry out certain treatments. Is suitable for diagnosis of bronchial lesions, upper digestive tract lesions, lower digestive tract lesions, otorhinolaryngopathy and the like.

Most of the existing endoscopes are transmitted in a wired mode, the endoscopes transmit shooting images to external display equipment through connecting cables for real-time display, stay wire connection is troublesome and inconvenient to operate, and in the operation process of operation, the wires often have certain influence on the operation of doctors, the operation effect and efficiency are affected, and medical accidents are easily caused and the operation is prevented. Although wireless transmission endoscopes are proposed for wired problems later, when the wireless endoscopes are used, signal exchange needs are needed, so that hardware is heated, the prior art generally adopts an internal built-in cold gel to absorb heat and then the heat is led out through a metal connecting pipe, but most of heat discharged in the mode is concentrated in the interior and cannot be discharged in clinical use, and no existing mechanism for radiating heat in a mode of detachable radiating the shell and internally arranging radiating fins exists;

therefore, a heat sink device of an endoscope wireless transmission structure is proposed to solve the above-mentioned problems.

Disclosure of Invention

In order to overcome the above-mentioned drawbacks of the prior art, embodiments of the present utility model provide a heat dissipating device with a wireless transmission structure for an endoscope, so as to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the heat dissipation device comprises an attraction port, one end of the attraction port is fixedly connected with a connecting pipe, one end of the connecting pipe is penetrated and provided with an aviation socket, one end of the aviation socket is inserted with an aviation contact pin, one end of the aviation contact pin is fixedly connected with a first shell, a heating source is installed in the first shell, a soaking plate is installed at the top end of the heating source, the soaking plate is connected with the connecting pipe, and the heating source transmits the heating source to the soaking plate. The vapor chamber transmits a heat source to the connecting pipe, and the connecting pipe transmits the heat source to the suction port.

Further, the blind hole is formed in the outer wall of the first shell, the first shell is cylindrical, and fins are arranged on the inner wall of the first shell.

Further, the front end part of the first shell is fixedly connected with a sleeve layer, and a notch is formed in the front end of the sleeve layer and used for disassembling the first shell to conduct open type heat dissipation treatment.

Further, the buckle is installed through the breach butt joint to the front end of sleeve layer, the bottom fixedly connected with butt joint cover body of buckle, be integrated into one piece structure between butt joint cover body and the first casing, and disassemble first casing through the mode that rotates the breach of first casing control sleeve layer front end and buckle break away from thereby dispel the heat.

Further, the blind holes are provided with four groups, and the apertures of the four groups of blind holes are two millimeters.

Further, one end of the butt joint cover body is fixedly connected with the second shell, and the first shell is connected with the second shell through the butt joint cover body.

Further, one end of the first shell is inserted and provided with a heat dissipation controller.

Further, one end of the heat dissipation controller is fixedly connected with a first I-shaped heat dissipation fin, and the middle part of one end of the first I-shaped heat dissipation fin is fixedly connected with an aluminum strip.

Further, one end of the aluminum strip is fixedly connected with a second I-shaped radiating fin, and one surface of the second I-shaped radiating fin is covered with a condensation silicone grease body.

Furthermore, the first I-shaped radiating fins and the second I-shaped radiating fins are respectively provided with two groups of front and back sides of the heating source, and one side of the second I-shaped radiating fins and one side of the heating source are filled with condensed silica gel.

The utility model has the technical effects and advantages that:

1. compared with the prior art, the endoscope wireless image transmission structureThe heat dissipation device passes throughVapor chamber, first shell, blind holes and metal finsRelationship ofWhen later stage uses, can dispel the heat to the inside of first casing through the metal fin, cooperate the blind hole can dispel the heat to the inside endoscope component of first casing, compare in the inside silica gel heat dissipation that uses of traditional endoscope, the radiating effect of the device is better. Meanwhile, the device adopts a mode of clamping the notch at the front end of the sleeve layer with the buckle to mount the first shell, and the notch at the front end of the sleeve layer is controlled to be separated from the buckle by rotating the first shell to perform disassembly type heat dissipation or rapid replacement of the shell.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic view of the external structure of the present utility model.

FIG. 3 is a schematic view of a metal fin according to the present utility model.

FIG. 4 is a schematic view of a sleeve layer structure according to the present utility model.

Fig. 5 is a schematic diagram of an i-shaped heat dissipation fin according to the present utility model.

The reference numerals are: 1. a suction port; 2. a connecting pipe; 3. aviation socket; 4. a butt joint cover body; 5. a first housing; 6. aviation contact pin; 7. a soaking plate; 8. a heat source; 9. a blind hole; 10. a metal fin; 11. a sleeve layer; 12. a buckle; 13. a second housing; 14. a first I-shaped heat radiating fin; 15. a second I-shaped heat radiating fin; 16. an aluminum single strip; 17. a heat dissipation controller; 18. condensing the silicone grease.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

The heat dissipation device of the wireless image transmission structure of the endoscope shown in the attached drawings 1-4 comprises a suction port 1, one end fixedly connected with connecting pipe 2 of the suction port 1, one end of the connecting pipe 2 is penetrated and installed with an aviation socket 3, one end of the aviation socket 3 is inserted and connected with an aviation contact pin 6, one end part fixedly connected with a first shell 5 of the aviation contact pin 6, a heat generation source 8 is installed in the first shell 5, a soaking plate 7 is installed at the top end of the heat generation source 8, the soaking plate 7 is connected with the connecting pipe 2, the heat generation source 8 transmits a heat source to the soaking plate 7, the soaking plate 7 transmits the heat source to the connecting pipe 2, the connecting pipe 2 transmits the heat source to the suction port 1, a blind hole 9 is formed in the outer wall of the first shell 5, the first shell 5 is cylindrical, a fin 10 is arranged on the inner wall of the first shell 5, a sleeve layer 11 is fixedly connected with the front end part of the first shell 5, a notch is arranged at the front end of the sleeve layer 11 and is used for disassembling the first shell 5 to be opened, the heat dissipation layer 11 is installed at the front end 12 of the sleeve layer, the sleeve layer is connected with the first shell 4 through a notch 12, the first shell 4 is connected with the first shell 4 through a butt joint structure, and the first shell 4 is connected with the first shell 4 through a notch 13, and the first shell 4 is connected with the first shell 4 through a butt joint structure, and the notch 13 is fixedly connected with the first shell 4.

Wherein: four sets of blind holes 9 cooperate with the fin 10 of inside, and guide the heat that produces inside through annular fin 10 and dispel, thereby dispel the heat with the inside of first casing 5, be difficult for detaining in the inside of first casing 5, adopted the design of sleeve layer 11 cooperation breach simultaneously to connect buckle 12, consequently rotate the sleeve layer 11 of first casing 5 drive one end and can break away from with the butt joint cover body 4, thereby accomplish the whole excision of first casing 5 and carry out open-type heat dissipation.

Example two

Example two

On the basis of the first embodiment, the scheme in the first embodiment is further introduced in detail in combination with the following specific working mode, as shown in fig. 1 to 5, and described in detail below

As a preferred embodiment, one end of the first housing 5 is inserted and connected with a heat dissipation controller 17, the heat dissipation controller 17 is fixedly connected with a first i-shaped heat dissipation fin 14 at one end of the heat dissipation controller 17, a single aluminum strip 16 is fixedly connected with the middle of one end of the first i-shaped heat dissipation fin 14, a second i-shaped heat dissipation fin 15 is fixedly connected with one end of the single aluminum strip 16, one surface of the second i-shaped heat dissipation fin 15 is covered with a condensation silicone grease body 18, two groups of front and back surfaces of the first i-shaped heat dissipation fin 14 and the second i-shaped heat dissipation fin 15 are respectively provided with two groups of heat generation sources 8, and one side of the second i-shaped heat dissipation fin 15 and one side of the heat generation sources 8 are also filled with condensation silicone.

Wherein: the first i-shaped radiating fins 14 and the second i-shaped radiating fins 15 are covered and pressed at one end of the heating source 8 by adopting condensed silicone grease, in the process, the condensed silicone gel can also play a certain heat conduction function, the second i-shaped radiating fins 15 are adopted for carrying out heat absorption treatment, in addition, the two groups of second i-shaped radiating fins 15 and the first i-shaped radiating fins 14 are designed for radiating the front side and the back side of the heating source 8, and in the radiating process, the radiating controller 17 is adopted for controlling the fins to carry out heat radiation treatment.

The working process of the utility model is as follows:

when the heat dissipating device of the wireless transmission structure of the endoscope is matched with the endoscope in the later period, firstly, the heat dissipating structure is arranged in the wireless transmission structure of the endoscope, and when the heat dissipating device is applied to heat dissipation, the fins 10 of the annular heat dissipating structure are used for absorbing the whole heat generated by the heat generating source 8 in the first shell 5, and the blind holes 9 arranged on the outer surface of the first shell 5 are used for dissipating the heat energy absorbed by the fins in the first shell 5. Meanwhile, the first shell 5 is rotated to control the notch at the front end of the sleeve layer 11 connected with the front end of the first shell to be separated from the buckle 12 connected with the cover body 4, so that the first shell is disassembled for heat dissipation. Meanwhile, the heating source 8 inside disperses a part of heat by adopting the vapor chamber 7, and meanwhile, the first shell 5 and the second shell 13 of the device are matched by adopting the aviation socket 3 and the aviation contact pin 6, so that the heat connection output of the connecting pipe 2 transmitted to the suction port 1 is completed. In addition, on the basis of the heat radiation structure, the device is provided with the second I-shaped heat radiation fins 15 on the side face of the heat source 8, condensation silica gel is adopted for lamination, the second I-shaped heat radiation fins 15 are adopted for absorbing heat on the side face of the heat source 8, heat conduction is completed through the aluminum single strip 16 and the first I-shaped heat radiation fins 14, and meanwhile the absorbed heat can be radiated through the blind holes 9, so that the working principle of the device is achieved.

Finally: the foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

Claims (10)

1. The heat dissipation device of the wireless image transmission structure of the endoscope comprises an attraction port (1), and is characterized in that; one end fixedly connected with connecting pipe (2) of suction inlet (1), aviation socket (3) are installed in the one end penetration of connecting pipe (2), aviation socket (3) one end peg graft have aviation contact pin (6), the one end fixedly connected with first casing (5) of aviation contact pin (6), internally mounted of first casing (5) has heat source (8), vapor chamber (7) are installed on the top of heat source (8), vapor chamber (7) are connected with connecting pipe (2), heat source (8) transmit the heat source to vapor chamber (7), vapor chamber (7) transmit the heat source to connecting pipe (2), connecting pipe (2) transmit the heat source to suction inlet (1).

2. The heat sink for an endoscopic wireless transmission structure of claim 1, wherein: the outer wall of the first shell (5) is provided with a blind hole (9), the first shell (5) is cylindrical, and the inner wall of the first shell (5) is provided with fins (10).

3. The heat sink for an endoscopic wireless transmission structure according to claim 2, wherein: the front end part of the first shell (5) is fixedly connected with a sleeve layer (11), and a notch is formed in the front end of the sleeve layer (11).

4. The heat sink for an endoscopic wireless transmission structure of claim 3, wherein: the front end of sleeve layer (11) is through breach butt joint installation buckle (12), the bottom fixedly connected with butt joint cover body (4) of buckle (12), be integrated into one piece structure between butt joint cover body (4) and first casing (5), and accessible rotates first casing (5) control sleeve layer (11) front end's breach and the mode that buckle (12) break away from disassemble first casing (5).

5. The heat sink for an endoscopic wireless transmission structure according to claim 2, wherein: the blind holes (9) are provided with four groups, and the apertures of the four groups of blind holes are two millimeters.

6. The heat sink for an endoscopic wireless transmission structure according to claim 4, wherein: one end of the butt joint cover body (4) is fixedly connected with the second shell (13), and the first shell (5) is connected with the second shell (13) through the butt joint cover body (4).

7. The heat sink of an endoscopic wireless transmission structure according to claim 6, wherein: one end of the first shell (5) is inserted and connected with a heat dissipation controller (17).

8. The heat sink of an endoscopic wireless transmission structure according to claim 7, wherein: one end of the heat dissipation controller (17) is fixedly connected with a first I-shaped heat dissipation fin (14), and the middle part of one end of the first I-shaped heat dissipation fin (14) is fixedly connected with an aluminum single strip (16).

9. The heat sink of an endoscopic wireless transmission structure according to claim 8, wherein: one end of the aluminum single strip (16) is fixedly connected with a second I-shaped radiating fin (15), and one surface of the second I-shaped radiating fin (15) is covered with a condensation silicone grease body (18).

10. The heat sink of an endoscopic wireless transmission structure according to claim 8, wherein: the first I-shaped radiating fins (14) and the second I-shaped radiating fins (15) are respectively provided with two groups of front and back sides of the heating source (8), and one sides of the second I-shaped radiating fins (15) and one side of the heating source (8) are filled with condensed silica gel.