CN215128382U - Portable intelligent urethrocystoscope system - Google Patents

Abstract

The utility model discloses a portable intelligent urethrocystoscope system, which comprises a sheath and a handle hermetically connected with the tail end of the sheath, wherein a central channel is arranged in the sheath, an endoscope is fixedly arranged on the handle and is arranged in the central channel in a penetrating way, a display is fixedly arranged outside the handle, and the endoscope and the display are both connected with a controller arranged in the handle; the endoscope sheath is also internally provided with a water inlet passage and a water outlet passage, the water inlet passage is provided with a water inlet formed on the outer wall of the endoscope sheath and a water filling port formed at the head end of the endoscope sheath, and the water outlet passage is provided with a water suction port formed at the head end of the endoscope sheath and a water outlet formed on the outer wall of the endoscope sheath. The cystoscope system can be used for examining a patient in a common treatment room or ward without taking a complete lithotomy position by the patient; and the water inlet passage and the water outlet passage are arranged in the endoscope sheath, so that the bladder cavity can be synchronously inflated in the cystoscope examination process, the observation visual field of the endoscope can be kept clear, and the operation is very convenient and fast.

Description

Portable intelligent urethrocystoscope system

Technical Field

The utility model belongs to the technical field of medical instrument, in particular to portable intelligent urethrocystoscope system.

Background

When the traditional cystoscope is used, a special cystoscope room or an operating room is required to be equipped, a large cystoscope examination and imaging system is required to be used, and a doctor needs to operate in the lithotomy position of a patient, so that a lot of primary hospitals are difficult to carry out cystoscope operations due to the fact that the large equipment cannot be purchased, and the discomfort psychology of part of patients is caused by the position of a detected body in the examination process.

Meanwhile, only the examiner can see the examination process, other doctors or patients cannot watch the whole examination process, only partial screen shot picture reports can be seen after the examination, and the operation and observation are inconvenient.

In order to solve the problems, the chinese utility model patent with publication number CN211933997U discloses a hand-held cystoscope with a visual display, which comprises a fixed tube, wherein one end of the fixed tube is provided with an endoscope tube, the other end is connected with an outer cystoscope tube, one end of the outer cystoscope tube, which is far away from the fixed tube, is provided with an inner cystoscope tube, and one end of the inner cystoscope tube, which is far away from the outer cystoscope tube, is fixed with a camera; the side wall of the fixed tube is rotatably connected with a display through a rotating shaft, and a light source signal plug which is convenient to connect with signal equipment through a wire is further fixed on one side of the fixed tube.

The cystoscope is small and handheld, is provided with a visual display, and is low in manufacturing cost and use cost. However, when the cystoscope is used, the bladder must be filled with liquid to observe, and mucus, blood and the like in the operation visual field need to be cleaned in time; therefore, the cystoscope needs to be additionally provided with a liquid flushing and absorbing device when in use, and the observation process becomes more complicated.

SUMMERY OF THE UTILITY MODEL

The invention aims at providing a portable intelligent urethrocystoscope system, which is not only small and portable, but also can simultaneously fill liquid into a bladder cavity and keep a clear operation visual field at any time.

In order to achieve the purpose, the technical scheme of the utility model is as follows:

a portable intelligent urethrocystoscope system comprises a sheath and a handle hermetically connected with the tail end of the sheath, wherein a central channel is arranged in the sheath, an endoscope is fixedly arranged on the handle and penetrates through the central channel, a display is fixedly arranged on the outer side of the handle, and the endoscope and the display are connected with a controller arranged in the handle;

the endoscope sheath is characterized in that a water inlet passage and a water outlet passage are also formed in the endoscope sheath, the water inlet passage is provided with a water inlet formed on the outer wall of the endoscope sheath and a water filling port formed at the head end of the endoscope sheath, and the water outlet passage is provided with a water suction port formed at the head end of the endoscope sheath and a water outlet formed on the outer wall of the endoscope sheath.

The utility model discloses in, the handle outside directly sets firmly little display, places the image that the controller in the handle can be shot with the scope in observing the field of vision in real time and shows on this little display in place, consequently need not to use large-scale cystoscope inspection and video picture system, can inspect the patient in ordinary treatment room or ward, and need not the patient and get complete lithotomy position.

In the utility model, the endoscope sheath is directly provided with the water inlet passage and the water outlet passage, wherein clean clear water can be filled into the bladder cavity through the water inlet passage, so that the bladder cavity is filled with liquid, and the normal operation of the examination is ensured; when the observation or operation visual field is influenced by the existence of mucus or blood in the bladder cavity, clear water can be continuously filled into the bladder cavity through the water inlet passage, the observation visual field of the endoscope is kept clear while the bladder cavity is filled, and sewage mixed with the mucus or blood is discharged through the water outlet passage; the whole process of filling the bladder cavity and making the observation visual field clear is carried out synchronously with the cystoscope examination process, and the operation is very convenient and fast.

In the above portable intelligent urethrocystoscope system, the water inlet passage is formed among the water inlet, the central passage and the water filling port, and the water outlet passage is formed among the water suction port, the central passage and the water outlet. At the moment, only a central channel is arranged in the endoscope sheath, and the central channel is used as an accommodating channel of the endoscope and also used as a water inlet channel or a water outlet channel; but it is inconvenient to carry out the water inlet and outlet simultaneously.

Or, in the above portable intelligent urethrocystoscope system, the endoscope sheath is further provided with a water inlet channel, and the water inlet channel is formed among the water inlet, the water inlet channel and the water filling port;

either or in combination with each other, or,

the endoscope sheath is also internally provided with a water outlet channel, and the water outlet channel is formed among the water suction port, the water outlet channel and the water outlet.

At the moment, the endoscope sheath is internally provided with a central channel, and is additionally provided with a water inlet channel and/or a water outlet channel; when only additionally setting up inhalant canal, the central channel uses as out water channel promptly simultaneously, and when only additionally setting up out water channel, the central channel uses as into water channel promptly simultaneously, and when setting up inhalant canal and play water channel simultaneously, the central channel only is used for wearing to establish the scope.

In the above portable intelligent urethrocystoscope system, the water inlet channel comprises at least two water inlet channels, and all the water inlet channels are communicated with the water inlet through a water inlet cavity;

either or in combination with each other, or,

the water outlet channels comprise at least two water outlet channels, and all the water outlet channels are communicated with the water outlet through a water outlet cavity;

the water inlet channel and/or the water outlet channel are uniformly arranged in the circumferential direction by taking the central channel as a center.

The arrangement of the plurality of water inlet channels and the plurality of water outlet channels can improve the water inlet efficiency and the water outlet efficiency.

In the portable intelligent urethrocystoscope system, the water inlet is provided with a water inlet pipe joint convenient for installing a water inlet pipe, the water outlet is provided with a water outlet pipe joint convenient for installing a water outlet pipe, and the water inlet pipe joint and the water outlet pipe joint are integrally formed with the scope sheath.

In the portable intelligent urethrocystoscope system, the sheath is detachably and fixedly connected with the handle. So that the sheath can be conveniently detached for replacement or disinfection.

In the portable intelligent urethrocystoscope system, the handle head end is fixedly provided with a sealing plug head which is in sealing fit with the inner peripheral wall of the scope sheath;

one end of the sealing plug head, which is far away from the endoscope sheath, is provided with a convex ring, and the tail end of the endoscope sheath is abutted against the convex ring and is in sealing fit with the convex ring;

the endoscope penetrates through the sealing plug head, and is arranged on one side of the sealing plug head facing the handle, and the endoscope is fixedly connected with the handle. Therefore, the endoscope is convenient to be detached from the handle for replacement or disinfection.

In the above-mentioned portable intelligent urethrocystoscope system, the scope be the fiberscope, in the sealed chock plug towards the one side of handle, this fiberscope periphery has the fixed cover of being convenient for to link firmly with the handle.

In the portable intelligent urethrocystoscope system, a pushing raised head is formed at the head end of the endoscope sheath, and the pushing raised head and the endoscope sheath are arranged at an obtuse angle;

the included angle between the pushing convex head and the endoscope sheath is more than 150 degrees, and the pushing convex head has a smooth surface.

The pushing convex head is arranged to enable the head end of the cystoscope to smoothly enter a bladder cavity from a urethra, but in order to avoid the damage of the pushing convex head to the urethra, the included angle between the pushing convex head and the cystoscope sheath is set to be larger than 150 degrees, and the pushing convex head is set to be provided with a smooth surface.

In the portable intelligent urethrocystoscope system, the outer circumference of the handle is rotationally connected with a rotary joint seat, and the rotary joint seat is in sealing fit with the handle;

the display is fixedly arranged on the rotary joint seat, a plurality of first conductive terminals connected with the controller are arranged on the outer peripheral wall of the handle, and a plurality of second conductive terminals connected with the display are arranged on the inner peripheral wall of the rotary joint seat;

the first conductive terminals are connected with the second conductive terminals in a contact mode, the first conductive terminals are evenly arranged in the circumferential direction of the handle, and the second conductive terminals are evenly arranged in the circumferential direction of the rotary joint seat.

The display is fixed on the rotary joint seat, so that when the handle is rotated (to rotate the sheath) in the examination process, the display can rotate around the handle to always face the operator. And the first conductive terminal and the second conductive terminal which are respectively arranged on the handle and the rotary joint seat can be always contacted and connected in the rotating process of the rotary joint seat, so that the display is always connected with the controller.

In the above portable intelligent urethrocystoscope system, the system further comprises a wireless image transmitter, wherein the wireless image transmitter comprises a transmitting end and a receiving end, the transmitting end is arranged in the handle and connected with the controller, and the receiving end is connected with the computer. The controller can transmit the dynamic image recorded and stored in the checking process to the computer through the wireless image transmitter, so that inspectors or patients can repeatedly watch the dynamic image data from the computer, the case study of special cases is facilitated, and the dynamic image data can be edited on the computer to make a report.

Compared with the prior art, the beneficial effects of the utility model are embodied in:

(1) the utility model discloses in, the handle outside directly sets firmly little display, places the image that the controller in the handle can be shot with the scope in observing the field of vision in real time and shows on this little display in place, consequently need not to use large-scale cystoscope inspection and video picture system, can inspect the patient in ordinary treatment room or ward, and need not the patient and get complete lithotomy position.

(2) In the utility model, the endoscope sheath is directly provided with the water inlet passage and the water outlet passage, wherein clean clear water can be filled into the bladder cavity through the water inlet passage, so that the bladder cavity is filled with liquid, and the normal operation of the examination is ensured; when the observation visual field is influenced by the existence of mucus or blood in the bladder cavity, clear water can be continuously filled into the bladder cavity through the water inlet passage, the observation visual field of the endoscope is kept clear while the bladder cavity is filled, and sewage mixed with the mucus or blood is discharged through the water outlet passage; the whole process of filling the bladder cavity and making the observation visual field clear is carried out synchronously with the cystoscope examination process, and the operation is very convenient and fast.

(3) The utility model discloses in, inhalant canal and exhalant canal all are equipped with two at least, and inhalant canal and exhalant canal all use central channel to evenly arrange as center circumference, set up many inhalant canals and exhalant canal and can improve into water and go out water efficiency.

(4) The utility model discloses in, be between mirror sheath and the handle, between scope and the handle detachable linking firmly, so convenient dismantles mirror sheath or scope from the handle and gets off to change or disinfect.

(5) The utility model fixes the display on the rotary joint seat, so that when the handle is rotated (to rotate the sheath) in the examination process, the display can rotate around the handle to always face the operator; and the first conductive terminal and the second conductive terminal which are respectively arranged on the handle and the rotary joint seat can be always contacted and connected in the rotating process of the rotary joint seat, so that the display is always connected with the controller.

(6) The utility model discloses in, set up the switch that is used for adjusting scope built-in light source luminance on the handle, the person of executing the operation can adjust the illumination brightness in the observation field of vision at any time in operation process.

(8) The utility model discloses in, the controller can record and the dynamic image who saves in the inspection process transmits for the computer through wireless image transmitter, and inspector or patient homoenergetic can be followed the computer and repeatedly watched this dynamic image data, are favorable to the case discussion of special case to can edit in order to make the report on the computer.

Drawings

FIG. 1 is a schematic structural view of the portable intelligent urethrocystoscope system of the present invention;

FIG. 2 is a partial cross-sectional view A-A of FIG. 1;

FIG. 3 is a schematic view of the connection structure of the rotary joint seat and the handle in FIG. 1;

FIG. 4 is a block diagram of the portable intelligent urethrocystoscope system of the present invention;

FIG. 5 is another schematic structural view of the portable intelligent urethrocystoscope system of the present invention;

FIG. 6 is another schematic structural view of the portable intelligent urethrocystoscope system of the present invention;

fig. 7 is a partial sectional view of B-B in fig. 6.

Detailed Description

The technical solution of the present invention will be further described in detail with reference to the accompanying drawings and the detailed description.

Example 1

As shown in fig. 1 and fig. 2, the portable intelligent urethrocystoscope system of the present embodiment includes a sheath 1 and a handle 2 connected to the tail end of the sheath 1 in a sealing manner, a central channel 11 is disposed in the sheath 1, an endoscope 3 is also fixedly disposed at the head end of the handle 2, and the endoscope 3 is disposed in the central channel 11 in a penetrating manner.

Scope 3 that this embodiment chose for use is the fiberscope, and the fiberscope is not only tiny, soft, can bend at will, be difficult for damaging urethra and bladder chamber, and the leaded light performance is good moreover, can observe small pathological change.

As shown in fig. 1, a sealing plug 4 is hermetically installed at the tail end of the endoscope 3, the endoscope 3 penetrates through the sealing plug 4, a fixing sleeve 31 is provided at the periphery of the endoscope 3 on the side of the sealing plug 4 facing the handle 2, and the fixing connection with the handle 2 through the fixing sleeve 31 can adopt a threaded connection mode or an embedding mode. The endoscope 3 and the sealing plug 4 can be separated from the handle 2, thereby facilitating the disinfection or replacement of the endoscope 3 and the sealing plug 4.

In the embodiment, the sheath 1 is detachably connected with the handle 2, so that the sheath 1 can be made of disposable materials, and repeated use is avoided.

As can be seen from fig. 1, one end of the sealing plug 4 away from the endoscope sheath 1 is provided with a convex ring 41, the tail end of the endoscope sheath 1 sleeved outside the endoscope 3 abuts against the convex ring 41 and is in sealing fit with the convex ring 41, and the inner peripheral wall of the endoscope sheath 1 is in sealing fit with the sealing plug 4. In this embodiment, the sealing plug 4 and the convex ring 41 are integrally formed and made of rubber material.

As shown in fig. 1 and fig. 2, in this embodiment, a water inlet channel 12 and a water outlet channel 13 located at the periphery of the central channel 11 are further formed in the sheath 1, the water inlet channel 12 has a water inlet 101 formed on the outer wall of the sheath 1 and a water filling opening 102 formed at the head end of the sheath 1, and a water inlet passage 100 is formed among the water inlet 101, the water inlet channel and the water filling opening 102; the water outlet channel 13 is provided with a water suction port 201 formed at the head end of the sheath 1 and a water outlet 202 formed on the outer wall of the sheath, and a water outlet passage 200 is formed among the water suction port 201, the water outlet channel and the water outlet 202; the water inlet 101 is provided with a water inlet pipe joint 14 convenient for installing a water inlet pipe, the water outlet 202 is provided with a water outlet pipe joint 15 convenient for installing a water outlet pipe, and the water inlet pipe joint 14 and the water outlet pipe joint 15 are integrally formed with the endoscope sheath 1.

Wherein, clean water can be filled into the bladder cavity through the water inlet passage 100, so that the bladder cavity is filled with liquid, and the normal operation of the examination is ensured; when the observation visual field is influenced by the existence of mucus or blood in the bladder cavity, clear water can be continuously filled into the bladder cavity through the water inlet passage 100, the observation visual field of the endoscope 3 is kept clear while the bladder cavity is filled, and sewage mixed with mucus or blood is discharged through the water outlet passage 200; the whole process of filling the bladder cavity and making the operation visual field clear is carried out synchronously with the cystoscope examination process, and the operation is very convenient and fast.

As shown in figure 1, in order to ensure that the head end of the endoscope sheath 1 can smoothly enter the bladder cavity from the urethra, a pushing convex head 16 is formed at the head end of the endoscope sheath 1; in order to avoid the injury of the pushing nose 16 to the urethra, the included angle α between the pushing nose 16 and the sheath 1 is generally set to be more than 150 °, and the pushing nose 16 is set to have a smooth surface.

As shown in fig. 4, in the present embodiment, a controller 5 is disposed in the handle 2, and the endoscope 3 is electrically connected to the controller 5 while being fixedly connected to the handle 2; the outer side of the handle 2 is also provided with a small display 6, and the controller 5 can display the image shot by the endoscope 3 in the observation field of view on the small display 6 in real time, so that a large cystoscopy and imaging system is not needed, the patient can be examined in a common treatment room or ward, and the patient does not need to take a complete lithotomy position.

As shown in fig. 1 and 3, in the present embodiment, a rotary joint base 8 is rotatably connected to the outer periphery of the handle 2, the rotary joint base 8 is in sealing fit with the handle 2, and the display 6 is fixedly arranged on the rotary joint base 8, so that when the handle 2 is rotated (to rotate the endoscope sheath 1) during the examination process, the display 6 can rotate around the handle to always face the operator; the outer peripheral wall of the handle 2 is provided with a plurality of first conductive terminals 9 connected with the controller 5, and the inner peripheral wall of the rotary joint seat 8 is provided with a plurality of second conductive terminals 10 connected with the display 6; the first conductive terminals 9 are uniformly arranged around the circumference of the handle, the second conductive terminals 10 are uniformly arranged around the circumference of the rotary joint seat 8, and no matter how the rotary joint seat 8 rotates around the handle 2, the first conductive terminals 9 and the second conductive terminals 10 are always in one-to-one corresponding contact connection so as to ensure that the display 6 is always connected with the controller 5.

Meanwhile, as shown in fig. 4, the portable intelligent urethrocystoscope system of this embodiment further includes a wireless image transmitter 7, and the wireless image transmitter 7 includes a transmitting end 71 and a receiving end 72, wherein the transmitting end 71 is also built in the handle 2 and connected to the controller 5, and the receiving end 72 is connected to the computer 11, and the computer may be a common computer. The controller 5 can transmit the dynamic image recorded and stored in the examination process to the computer 11 through the wireless image transmitter 7, so that both examiners and patients can repeatedly watch the dynamic image data from the computer 11, thus being beneficial to the case study of special cases and being capable of editing on the computer 11 to make reports.

A power supply (not shown in the figure) convenient for supplying power to the display 6 and the controller 5 is further arranged in the handle 2, and a charging interface (not shown in the figure) convenient for charging the power supply is arranged at the tail end of the handle 2. In addition, as shown in fig. 1, a rotary switch 12 for adjusting the brightness of the built-in light source of the endoscope is further disposed on the handle, so that the operator can adjust the brightness of the light in the observation field at any time during the operation.

The working principle of the portable intelligent urethrocystoscope system of the embodiment is as follows:

the endoscope sheath 1 and the endoscope 3 enter the bladder cavity through the urethra together, and the controller 5 displays the image shot by the endoscope 3 in the observation visual field on the small-sized display 6 in real time; after the endoscope sheath 1 and the endoscope 3 enter the bladder cavity, a water supply end connected with a water inlet pipe joint 14 can be opened, clean water is continuously filled into the bladder cavity from a water inlet 101 through a water inlet channel 12, the observation visual field of the endoscope 3 is kept clear while the bladder cavity is filled, sewage mixed with mucus or blood is discharged from a water outlet 202 through a water outlet channel 13, and a water outlet pipe connected with a water outlet pipe joint 15 can have a negative pressure function to drive the sewage to be discharged as soon as possible; after the examination is finished, the controller 5 transmits the dynamic image recorded and stored in the examination process to the computer 11 through the wireless image transmitter 7, so that an examiner or a patient can repeatedly watch the dynamic image data from the computer 11, the study of cases of special cases is facilitated, and the dynamic image data can be edited on the computer 11 to make a report.

Example 2

As shown in fig. 5, the portable intelligent urethrocystoscope system of the present embodiment has a structure substantially the same as that of embodiment 1, except that: in this embodiment, two water inlet channels 12 are arranged in the sheath 1, and the two water inlet channels 12 are both communicated with the water inlet 101 through a water inlet cavity 17; two water outlet channels 13 are also arranged in the endoscope sheath 1, and the two water outlet channels 13 are communicated with the water outlet 202 through a water outlet cavity 18;

the water inlet channels 12 and the water outlet channels 13 are uniformly arranged in the circumferential direction by taking the central channel 11 as a center.

Besides, the number of the water inlet channels 12 and the number of the water outlet channels 13 can be set to be other numbers, and the arrangement of the plurality of water inlet channels 12 and the plurality of water outlet channels 13 can improve the water inlet efficiency and the water outlet efficiency.

Example 3

The present embodiment is a portable intelligent urethrocystoscope system, which has a structure substantially the same as that of embodiment 1 or embodiment 2, except that: in this embodiment, only the water inlet channel 12 is disposed in the sheath 1, but no water outlet channel is disposed, the water outlet channel 200 is directly formed among the water inlet 201, the central channel 11 and the water outlet 202, and the central channel 11 is used as a water outlet channel at the same time.

In this embodiment, the water inlet passage 100 and the water outlet passage 200 can be used simultaneously.

Example 4

The present embodiment is a portable intelligent urethrocystoscope system, which has a structure substantially the same as that of embodiment 1 or embodiment 2, except that: in this embodiment, only the water outlet channel 13 is disposed in the sheath 1, but no water inlet channel is disposed, the water inlet passage 100 is directly formed among the water inlet 101, the central channel 11 and the water filling port 102, and the central channel 11 is used as a water inlet channel at the same time.

In this embodiment, the water inlet passage 100 and the water outlet passage 200 can be used simultaneously.

Example 5

As shown in fig. 6 and 7, the portable intelligent urethrocystoscope system of the present embodiment has a structure substantially the same as that of embodiment 1 or embodiment 2, except that: in this embodiment, a water inlet channel and a water outlet channel are not arranged in the sheath 1, the water inlet channel 100 is directly formed between the water inlet 101, the central channel 11 and the water filling port 102, the water outlet channel 200 is also directly formed between the water suction port 201, the central channel 11 and the water outlet 202, the central channel 11 is used as the water inlet channel 100 and the water outlet channel 200 at the same time, but the water inlet channel 100 and the water outlet channel 200 cannot be used at the same time.

Claims (10)

1. A portable intelligent urethrocystoscope system is characterized by comprising a sheath (1) and a handle (2) which is hermetically connected with the tail end of the sheath (1), wherein a central channel (11) is arranged in the sheath (1), an endoscope (3) is fixedly arranged on the handle (2), the endoscope (3) is arranged in the central channel (11) in a penetrating manner, a display (6) is fixedly arranged on the outer side of the handle (2), and the endoscope (3) and the display (6) are connected with a controller (5) which is arranged in the handle (2);

still be formed with inhalant canal (100) and exhalant canal (200) in sheath (1), inhalant canal (100) have water inlet (101) that form on sheath (1) outer wall and form in the water filling mouth (102) of sheath (1) head end, exhalant canal (200) have water sucking mouth (201) that form in sheath (1) head end and delivery port (202) that form on the sheath outer wall.

2. A portable intelligent urethrocystoscope system according to claim 1, wherein the water inlet passage (100) is formed between the water inlet (101), the central channel (11) and the water filling port (102), and the water outlet passage (200) is formed between the water suction port (201), the central channel (11) and the water outlet (202).

3. The portable intelligent urethrocystoscope system according to claim 1, wherein a water inlet channel (12) is further formed in the sheath (1), and the water inlet passage (100) is formed among the water inlet (101), the water inlet channel (12) and the water filling port (102);

either or in combination with each other, or,

the endoscope sheath (1) is also internally provided with a water outlet channel (13), and the water outlet channel (200) is formed among the water suction port (201), the water outlet channel (13) and the water outlet (202).

4. The portable intelligent urethrocystoscope system according to claim 3, wherein the water inlet channel (12) comprises at least two water inlet channels, and all the water inlet channels (12) are communicated with the water inlet (101) through an water inlet cavity (17);

either or in combination with each other, or,

the water outlet channels (13) comprise at least two, and all the water outlet channels (13) are communicated with the water outlet (202) through a water outlet cavity (18);

the water inlet channel (12) and/or the water outlet channel (13) are uniformly arranged in the circumferential direction by taking the central channel (11) as the center.

5. A portable intelligent urethrocystoscope system according to any one of claims 1-4, wherein a water inlet connector (14) for conveniently installing a water inlet pipe is arranged at the water inlet (101), a water outlet connector (15) for conveniently installing a water outlet pipe is arranged at the water outlet (202), and the water inlet connector (14) and the water outlet connector (15) are integrally formed with the scope sheath (1).

6. A portable intelligent urethrocystoscope system according to any one of claims 1-4, wherein the sheath (1) is detachably connected with the handle (2).

7. The portable intelligent urethrocystoscope system according to claim 6, wherein a sealing plug (4) is fixedly arranged at the head end of the handle (2), and the sealing plug (4) is in sealing fit with the inner peripheral wall of the scope sheath (1);

one end of the sealing plug head (4) far away from the endoscope sheath (1) is provided with a convex ring (41), and the tail end of the endoscope sheath (1) is abutted against the convex ring (41) and is in sealing fit with the convex ring (41);

the endoscope (3) penetrates through the sealing plug head (4), and is arranged on one side of the sealing plug head (4) facing the handle (2), and the endoscope (3) is fixedly connected with the handle (2).

8. A portable intelligent urethrocystoscope system according to any one of claims 1-4, wherein the head end of the sheath (1) is formed with a pushing projection head (16), and the pushing projection head (16) and the sheath (1) are arranged at an obtuse angle;

the included angle between the pushing convex head (16) and the endoscope sheath (1) is more than 150 degrees, and the pushing convex head (16) is provided with a smooth surface.

9. A portable intelligent urethrocystoscope system according to any one of claims 1-4, wherein a rotary joint seat (8) is rotatably connected to the outer periphery of the handle (2), and the rotary joint seat (8) is in sealing fit with the handle (2);

the display (6) is fixedly arranged on the rotary joint seat (8), a plurality of first conductive terminals (9) connected with the controller (5) are arranged on the outer peripheral wall of the handle (2), and a plurality of second conductive terminals (10) connected with the display (6) are arranged on the inner peripheral wall of the rotary joint seat (8);

the first conductive terminal (9) is connected with the second conductive terminal (10) in a contact mode, the first conductive terminal (9) is evenly arranged in the circumferential direction of the handle (2), and the second conductive terminal (10) is evenly arranged in the circumferential direction of the rotary joint seat (8).

10. A portable intelligent urethrocystoscope system according to any one of claims 1-4, further comprising a wireless image transmitter (7), wherein the wireless image transmitter (7) comprises a transmitting end (71) and a receiving end (72), the transmitting end (71) is built into the handle (2) and connected to the controller (5), and the receiving end (72) is connected to the computer (11).

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