CN219661651U - Endoscope wireless image transmission structure heat dissipation device - Google Patents

Abstract

The utility model discloses an endoscope wireless image transmission structure heat dissipation device, specifically related to the field of endoscopes, and includes a suction port. One end of the suction port is fixedly connected with a connecting pipe, and one end of the connecting pipe is installed with an aviation socket. One end of the aviation socket is connected with an aviation pin. Through the relationship between the vapor chamber, the first shell, the blind holes and the metal fins, the utility model can dissipate heat inside the first shell through the metal fins in later use, and cooperate with the blind holes to dissipate heat to the first shell. The endoscope element inside the casing dissipates heat. Compared with the traditional use of silicone heat dissipation inside the endoscope, the heat dissipation effect of this device is better. At the same time, the device uses the notch at the front end of the sleeve layer and the buckle to install the first shell. By rotating the first shell, the notch at the front end of the sleeve layer and the buckle are disengaged to perform disassembly heat dissipation or carry out heat dissipation. Quick replacement of housing.

Description

Endoscope wireless image transmission structure heat dissipation device

Technical field

The utility model relates to the field of endoscopes, and more specifically, the utility model relates to a heat dissipation device for an endoscope wireless image transmission structure.

Background technique

An endoscope is an optical instrument that is sent from the outside of the body through the natural orifice of the human body into the body to examine diseases in the body. It can directly observe the lesions in the internal cavity of organs, determine their location and scope, and can take pictures, biopsies or swabs. It greatly improves the accuracy of cancer diagnosis and enables certain treatments. It is suitable for the diagnosis of bronchial lesions, upper gastrointestinal tract lesions, lower gastrointestinal tract lesions and ear, nose and throat lesions.

Most of the existing endoscopes use wired transmission. The endoscope transmits the captured images to an external display device through a connecting cable for real-time display. The wire connection operation is troublesome and inconvenient. Moreover, during the surgical operation, the wire often causes damage to the doctor. The operation will have a certain impact, affecting the surgical effect and efficiency, easily causing medical accidents and hindering surgical operations. Although later people proposed wireless transmission endoscopes to solve the problem of wired endoscopes, when using wireless endoscopes, there is a need for signal exchange, which causes the hardware to heat up, and the existing technology generally uses internal built-in cold gel. to complete the heat absorption, and then export the heat through the metal connecting pipe. However, when this method of discharging heat is used clinically, most of the heat is concentrated inside and cannot be discharged, and there is no way to disassemble the shell for heat dissipation and have built-in heat sinks. Existing mechanisms for heat dissipation;

Therefore, an endoscope wireless image transmission structure heat dissipation device is proposed to solve the above problems.

Utility model content

In order to overcome the above-mentioned defects of the prior art, embodiments of the present invention provide an endoscope wireless image transmission structure heat dissipation device to solve the above-mentioned problems raised in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solution: an endoscope wireless image transmission structure heat dissipation device, including a suction port, one end of the suction port is fixedly connected with a connecting pipe, and one end of the connecting pipe is installed with an aviation socket. , one end of the aviation socket is connected with an aviation pin, one end of the aviation pin is fixedly connected to a first shell, a heat source is installed inside the first shell, and the top of the heat source is installed There is a vapor chamber, the vapor chamber is connected to the connecting pipe, and the heat source transmits the heat source to the vapor chamber. The vapor chamber transmits the heat source to the connecting pipe, and the connecting pipe transmits the heat source to the suction port.

Further, the outer wall of the first housing is provided with a blind hole, the first housing is cylindrical, and the inner wall of the first housing is provided with fins.

Furthermore, a sleeve layer is fixedly connected to the front end of the first housing, and a gap is provided at the front end of the sleeve layer for disassembling the first housing for open heat dissipation treatment.

Further, the front end of the sleeve layer is docked with a buckle through the gap, and the bottom end of the buckle is fixedly connected to a docking cover. The docking cover and the first shell are an integrated structure, and The first housing is disassembled by rotating the first housing to disengage the notch and buckle at the front end of the sleeve layer to dissipate heat.

Further, the blind holes are provided in four groups, and the diameters of the blind holes in the four groups are all two millimeters.

Further, one end of the docking cover is fixedly connected to the second housing, and the first housing is connected to the second housing through the docking cover.

Further, a heat dissipation controller is plugged into one end of the first housing.

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

Furthermore, a second I-shaped heat dissipation fin is fixedly connected to one end of the single aluminum strip, and one side of the second I-shaped heat dissipation fin is covered with a condensed silicone grease body.

Further, the first I-shaped heat dissipation fin and the second I-shaped heat dissipation fin are provided with two groups on the front and back sides of the heat source, and the second I-shaped heat dissipation fin and the heat source side are also provided with two groups. Condensed silica gel for filling.

Technical effects and advantages of this utility model:

1. Compared with the existing technology, the heat dissipation device of the endoscope wireless image transmission structure passes through the relationship between the vapor chamber, the first housing, the blind holes, and the metal fins. In later use, it can pass through the metal fins. The heat is dissipated inside the first housing, and the blind holes can be used to dissipate heat from the endoscope elements inside the first housing. Compared with the traditional use of silicone heat dissipation inside the endoscope, the heat dissipation effect of this device is better. At the same time, the device uses the notch at the front end of the sleeve layer and the buckle to install the first shell. By rotating the first shell, the notch at the front end of the sleeve layer and the buckle are disengaged to perform disassembly heat dissipation or Quick replacement of housing.

Description of drawings

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

Figure 2 is a schematic diagram of the external structure of the utility model.

Figure 3 is a schematic diagram of the structure of the metal fin of the present invention.

Figure 4 is a schematic diagram of the sleeve layer structure of the present utility model.

Figure 5 is a schematic structural diagram of the I-shaped heat dissipation fin of the present invention.

The reference numbers are: 1. Suction port; 2. Connecting pipe; 3. Aviation socket; 4. Docking cover; 5. First shell; 6. Aviation pin; 7. Vapor chamber; 8. Heat source; 9. Blind hole; 10. Metal fin; 11. Sleeve layer; 12. Buckle; 13. Second shell; 14. First I-shaped cooling fin; 15. Second I-shaped cooling fin; 16 , Aluminum single strip; 17. Heat dissipation controller; 18. Condensation silicone grease body.

Detailed ways

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. Obviously, the described embodiments are only part of the embodiments of the present utility model, not all implementations. example. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present utility model.

Embodiment 1

The endoscope wireless image transmission structure heat dissipation device shown in Figures 1 to 4 includes a suction port 1. One end of the suction port 1 is fixedly connected to a connecting pipe 2. One end of the connecting pipe 2 is installed with an aviation Socket 3. An aviation pin 6 is inserted into one end of the aviation socket 3. One end of the aviation pin 6 is fixedly connected to a first housing 5. A heat source 8 is installed inside the first housing 5. , a vapor chamber 7 is installed on the top of the heat source 8. The vapor chamber 7 is connected to the connecting pipe 2. The heat source 8 transmits the heat source to the vapor chamber 7. The vapor chamber 7 will The heat source is transmitted to the connecting pipe 2, and the connecting pipe 2 transmits the heat source to the suction port 1. A blind hole 9 is provided in the outer wall of the first housing 5. The first housing 5 is cylindrical. And the inner wall of the first housing 5 is provided with fins 10. The front end of the first housing 5 is fixedly connected to a sleeve layer 11. The front end of the sleeve layer 11 is provided with a gap for disassembling the first housing. The body 5 undergoes open heat dissipation treatment. The front end of the sleeve layer 11 is connected with a buckle 12 through a gap. The bottom end of the buckle 12 is fixedly connected with a docking cover 4. The docking cover 4 is connected to the first The shells 5 are of an integrated structure, and the first shell is disassembled by rotating the first shell 5 to control the gap at the front end of the sleeve layer 11 and the buckle 12 to dissipate heat. The blind hole 9 is provided with There are four groups, and the apertures of the blind holes in the four groups are all two millimeters. One end of the docking cover 4 is fixedly connected to the second housing 13, and the first housing 5 is connected to the second housing through the docking cover 4. 13.

Among them: four sets of blind holes 9 cooperate with the internal fins 10, and the annular fins 10 are used to guide and dissipate the heat generated inside, thereby dissipating the heat inside the first housing 5 and preventing it from being retained in the second housing 5. Inside the first shell 5, the sleeve layer 11 is designed to match the notch to connect the buckle 12. Therefore, rotating the first shell 5 drives the sleeve layer 11 at one end and the docking cover 4 to be separated, thereby completing the first step. The entire housing 5 is removed and used for open heat dissipation.

Embodiment 2

Embodiment 2

On the basis of Embodiment 1, the solution in Embodiment 1 is further detailed and introduced in combination with the following specific working methods, as shown in Figures 1 to 5. For details, see the description below.

As a preferred embodiment, a heat dissipation controller 17 is plugged into one end of the first housing 5 , and a first I-shaped heat dissipation fin 14 is fixedly connected to one end of the heat dissipation controller 17 . , the middle part of one end of the first I-shaped heat dissipation fin 14 is fixedly connected with an aluminum single strip 16, and one end of the said aluminum single strip 16 is fixedly connected with a second I-shaped heat dissipation fin 15, the second I-shaped heat dissipation fin 15 One side is covered with a condensed silicone grease body 18. The first I-shaped heat dissipation fins 14 and the second I-shaped heat dissipation fins 15 are both provided with two groups located on the front and back sides of the heat source 8, and the second I-shaped heat dissipation fins The sides of the fins 15 and the heat source 8 are also filled with condensed silica gel.

Among them: the first I-shaped heat dissipation fin 14 and the second I-shaped heat dissipation fin 15 are covered with condensed silicone grease and pressed on one end of the heat source 8. In this process, the condensed silicone gel can also play a certain heat conduction function. The second I-shaped heat dissipation fins 15 are used for heat absorption. In addition, the design of two sets of second I-shaped heat dissipation fins 15 and first I-shaped heat dissipation fins 14 dissipates heat from both front and back sides of the heat source 8, and during heat dissipation When, the heat dissipation controller 17 is used to control the fins for heat dissipation treatment.

The working process of this utility model is as follows:

When the endoscope wireless image transmission structure heat dissipation device is used with the endoscope in the later stage, the heat dissipation structure is first installed inside the endoscope wireless image transmission structure, and when used for heat dissipation, the annular heat dissipation structure is provided. The fins 10 absorb the entire heat generated by the heat source 8 inside the first housing 5 and dissipate the heat energy absorbed by the fins inside the first housing 5 through the blind holes 9 provided on the outer surface of the first housing 5 . At the same time, the first shell is disassembled by rotating the first shell 5 to control the gap at the front end of the sleeve layer 11 connected to the front end to disengage from the buckle 12 connected to the cover 4 to dissipate heat. At the same time, the internal heat source 8 uses a vapor chamber 7 to disperse part of the heat. At the same time, the first housing 5 and the second housing 13 of the device use an aviation socket 3 and an aviation pin 6 to cooperate, thereby completing the connecting pipe. 2 heat connection output transmitted to suction port 1. In addition, on the basis of this heat dissipation structure, the device is provided with a second I-shaped heat dissipation fin 15 on the side of the heat source 8 and is bonded with condensed silicone. The heat is absorbed, and the heat conduction is completed through the aluminum single strip 16 and the first I-shaped heat dissipation fin 14. At the same time, the absorbed heat can also be dissipated through the blind holes 9. This is the working principle of the device.

Finally: The above are only preferred embodiments of the present utility model, and are not intended to limit the utility model. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the utility model shall include Within the protection scope of the present utility model.

Claims (10)

1. Endoscope wireless image transmission structure heat dissipation device, including a suction port (1), characterized in that: one end of the suction port (1) is fixedly connected with a connecting pipe (2), and one end of the connecting pipe (2) An aviation socket (3) is installed throughout. An aviation pin (6) is inserted into one end of the aviation socket (3), and the first housing (5) is fixedly connected to one end of the aviation pin (6). A heat source (8) is installed inside the first housing (5), and a vapor chamber (7) is installed on the top of the heat source (8). The vapor chamber (7) and the connecting pipe (2) ) connection, the heat source (8) transmits the heat source to the vapor chamber (7), the vapor chamber (7) transmits the heat source to the connecting pipe (2), the connecting pipe (2) Transfer the heat source to the suction port (1). 2. The endoscope wireless image transmission structure heat dissipation device according to claim 1, characterized in that: the outer wall of the first housing (5) is provided with a blind hole (9), and the first housing (5) ) is cylindrical, and the inner wall of the first housing (5) is provided with fins (10). 3. The endoscope wireless image transmission structure heat dissipation device according to claim 2, characterized in that: a sleeve layer (11) is fixedly connected to the front end of the first housing (5), and the sleeve The front end of layer (11) is provided with a gap. 4. The endoscope wireless image transmission structure heat dissipation device according to claim 3, characterized in that: the front end of the sleeve layer (11) is connected with a buckle (12) through a gap, and the buckle (12) ) is fixedly connected to a docking cover (4) at its bottom end. The docking cover (4) and the first housing (5) are of an integrated structure, and the sleeve can be controlled by rotating the first housing (5). The first housing (5) is disassembled by disengaging the notch at the front end of the barrel layer (11) from the buckle (12). 5. The endoscope wireless image transmission structure heat dissipation device according to claim 2, characterized in that: the blind holes (9) are provided with four groups, and the apertures of the four groups of blind holes are all two millimeters. 6. The endoscope wireless image transmission structure heat dissipation device according to claim 4, characterized in that: one end of the docking cover (4) is fixedly connected to the second housing (13), and the first housing (13) 5) Connect the second housing (13) through the docking cover (4). 7. A heat dissipation device for an endoscope wireless image transmission structure according to claim 6, characterized in that a heat dissipation controller (17) is plugged into one end of the first housing (5). 8. An endoscope wireless image transmission structure heat dissipation device according to claim 7, characterized in that: one end of the heat dissipation controller (17) is fixedly connected with a first I-shaped heat dissipation fin (14), so An aluminum single strip (16) is fixedly connected to the middle part of one end of the first I-shaped heat dissipation fin (14). 9. An endoscope wireless image transmission structure heat dissipation device according to claim 8, characterized in that: one end of the aluminum single strip (16) is fixedly connected with a second I-shaped heat dissipation fin (15), and the One side of the second I-shaped heat dissipation fin (15) is covered with a condensed silicone grease body (18). 10. An endoscope wireless image transmission structure heat dissipation device according to claim 8, characterized in that: the first I-shaped heat dissipation fin (14) and the second I-shaped heat dissipation fin (15) are both provided with There are two groups located on the front and back sides of the heat source (8), and the second I-shaped heat dissipation fin (15) and the side of the heat source (8) are also filled with condensed silica gel.