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CN-224230513-U - Endoscope inner cavity drying device

CN224230513UCN 224230513 UCN224230513 UCN 224230513UCN-224230513-U

Abstract

The utility model provides an endoscope inner chamber drying device, belong to endoscope drying technology field, which comprises a housin, be equipped with an air source interface and at least one dry pipeline interface on the casing, be equipped with gas heating module in the casing, gas heating module is located between air source interface and the dry pipeline interface, gas heating module passes through the pipeline respectively with air source interface, dry pipeline interface connection, gas heating module can heat the gas of entering, the evaporation of the interior moisture of endoscope lumen can be accelerated to the hot air, drying time has been shortened greatly, current endoscope drying device has been solved, adopt cold wind to dry the lumen, lead to drying time relatively longer, influence drying efficiency's problem.

Inventors

  • Yin Fangyi
  • TIAN SHENGJIE
  • ZHANG YONGRUI
  • LI ANGUO
  • CHENG YUANSHU
  • LIU WEI

Assignees

  • 山东格贝森医疗科技有限公司

Dates

Publication Date
20260512
Application Date
20250515

Claims (9)

  1. 1. An endoscope inner cavity drying device comprises a shell (1) and is characterized in that an air source interface (4) and at least one drying pipeline interface (5) are arranged on the shell (1), an air heating module (13) is arranged in the shell (1), the air heating module (13) is located between the air source interface (4) and the drying pipeline interface (5), and the air heating module (13) is connected with the air source interface (4) and the drying pipeline interface (5) through pipelines respectively.
  2. 2. An endoscope lumen drying apparatus as claimed in claim 1, wherein a gas flow sensor (12) is provided in the line between the gas heating module (13) and the gas source interface (4).
  3. 3. An endoscope lumen drying apparatus according to claim 1, characterized in that a gas splitter (14) is provided in the housing (1), and the gas heating module (13) is connected to the plurality of drying line interfaces (5) via the gas splitter (14).
  4. 4. An endoscope lumen drying apparatus as set forth in claim 3, characterized in that a pressure sensor (17) is mounted on the gas shunt (14).
  5. 5. An endoscope lumen drying apparatus as claimed in claim 3, wherein the gas shunt (14) is connected to all of the drying line interfaces (5) via a plurality of lines, and a solenoid valve (15) and a flow switch (16) are provided on each line between the gas shunt (14) and the drying line interfaces (5).
  6. 6. An endoscope lumen drying apparatus as claimed in claim 1, wherein the back of the housing (1) is provided with a plurality of mounting holes (29).
  7. 7. The endoscope inner cavity drying device according to claim 1, wherein the back of the shell (1) is hinged with a hanging plate (6), and a plurality of mounting holes (29) are formed in the hanging plate (6).
  8. 8. The endoscope inner cavity drying device according to claim 1, wherein a battery (18) and a control board (11) are arranged in the shell (1), the display screen (2) and the card swiping module (3) are arranged on the shell (1), and the control board (11) is connected with the battery (18), the gas heating module (13), the display screen (2) and the card swiping module (3).
  9. 9. The endoscope inner cavity drying device according to claim 8, wherein a data export module (10) is arranged in the shell (1), a data interface (7) is arranged on the shell (1), and the data export module (10) is respectively connected with the data interface (7) and the control board (11).

Description

Endoscope inner cavity drying device Technical Field The utility model relates to the technical field of endoscope drying, in particular to an endoscope inner cavity drying device. Background Because the soft endoscope directly contacts internal organs of a human body and belongs to a reusable medical instrument, the endoscope needs to be disinfected and dried after being used, the drying is an important process for preventing the pollution of the digestive endoscope, the lumen and the surface of the endoscope are required to be thoroughly dried, the occurrence rate of the pollution of the endoscope is up to 80 percent due to insufficient drying, and the formation of a biological film can be accelerated due to insufficient drying of the endoscope. The surface drying treatment of the endoscope is simple in operation, so that the synchronous drying of a plurality of endoscope lumens is facilitated, the whole volume of the drying treatment device is small, the drying treatment device is convenient to use, an endoscope drying device (publication No. CN 109998454B) is arranged at present, an air inlet pipeline and a plurality of air outlet pipelines are arranged, each air outlet pipeline is correspondingly connected with one endoscope, so that air is blown into the lumens of the endoscope, synchronous drying of one or more endoscope lumens is realized, and the labor intensity is reduced. In the existing endoscope drying device, air is directly blown into a lumen of an endoscope, cold air is adopted to dry the lumen, the temperature difference between the cold air and moist air in the lumen of the endoscope and the temperature difference between the cold air and the wall of the tube are small, and the continuously blown cold air gradually enables the air humidity in the lumen to reach a saturated state, so that the drying time is relatively long, and the drying efficiency is affected; in addition, each pipe of the existing endoscope drying device is correspondingly provided with a pressure gauge module respectively for detecting air pressure, the pressure gauge modules are more in number, the use cost is high, and the equipment volume is inconvenient to reduce. Disclosure of utility model In order to solve the technical problems that the drying time is relatively long and the drying efficiency is affected due to the fact that cold air is adopted to dry a tube cavity in the conventional endoscope drying device in the background technology, the utility model provides the endoscope inner cavity drying device. The technical scheme of the utility model is as follows: The utility model provides an endoscope inner cavity drying device, which comprises a shell, wherein an air source interface and at least one drying pipeline interface are arranged on the shell, an air heating module is arranged in the shell, the air heating module is positioned between the air source interface and the drying pipeline interface and is respectively connected with the air source interface and the drying pipeline interface through pipelines, the air heating module can heat the entering air, and the hot air can accelerate the evaporation of water in the endoscope tube cavity, so that compared with cold air drying, the drying time is greatly shortened, and the drying efficiency is improved. Preferably, a gas flow sensor is arranged on a pipeline between the gas heating module and the gas source interface, the gas flow sensor can monitor the gas flow entering the gas heating module in real time, the gas flow entering the device can be precisely controlled, the gas with proper flow is ensured to enter the heating module, the drying effect is ensured, and the influence on the heating efficiency and the drying effect due to overlarge or undersize flow can be avoided. Preferably, the gas branching device is arranged in the shell, the gas heating module is connected with the drying pipeline interfaces through the gas branching device, and the gas branching device can uniformly distribute heated gas to the drying pipeline interfaces, so that drying treatment can be performed on a plurality of endoscopes simultaneously, drying efficiency is greatly improved, and the requirement of simultaneously treating a plurality of endoscopes is met. Preferably, the pressure sensor is arranged on the gas branching device, the pressure sensor can monitor the gas pressure in the gas branching device in real time, damage to the endoscope lumen due to overhigh pressure or influence on drying effect due to overlow pressure is prevented, the safety and stability of the whole drying process are guaranteed, and compared with the case that the pressure sensor is arranged on each pipeline independently, the cost is reduced, the wiring and maintenance process are simplified, the whole volume of the drying device is reduced conveniently, and meanwhile, the pressure monitoring is more representative. Preferably, the gas branching device is connected with all the drying pipelin