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CN-224207995-U - Full-flow temperature controllable instantaneous nano sedimentation reaction equipment

CN224207995UCN 224207995 UCN224207995 UCN 224207995UCN-224207995-U

Abstract

The utility model discloses full-process temperature-controllable instantaneous nano sedimentation reaction equipment which comprises a blast oven, wherein an inner cavity of the blast oven is a heating cavity, a plurality of temperature sensors are uniformly distributed on the inner wall of the heating cavity, a plurality of heating wires are uniformly distributed on the inner wall of the heating cavity, an adjustable movable plate support is mounted on the inner wall of the heating cavity, the FNP reaction under different temperature conditions is realized through the cooperation of the blast oven, the temperature sensors and other parts, the stable transmission of reactants under the high temperature environment is ensured by the design of a high temperature corrosion-resistant pipeline, the injection speed of a syringe pump is adjustable, the requirements of different experimental reaction rates are met, the flexibility and the applicability of the device are further enhanced, and meanwhile, the equipment is simple in structure, convenient to operate, suitable for laboratories and small-scale production, and good in use effect.

Inventors

  • SHI YULIN
  • WANG XING
  • WEI TINGTING
  • LI RUIMIN

Assignees

  • 新疆大学

Dates

Publication Date
20260508
Application Date
20250530

Claims (6)

  1. 1. The full-process temperature controllable instantaneous nano sedimentation reaction equipment comprises a blast oven (1) and is characterized in that an inner cavity of the blast oven (1) is a heating cavity (7), a plurality of temperature sensors (12) are uniformly distributed on the inner wall of the heating cavity (7), a plurality of heating wires (5) are uniformly distributed on the inner wall of the heating cavity (7), an adjustable movable plate support (8) is mounted on the inner wall of the heating cavity (7), an FNP reactor (9) is arranged above the adjustable movable plate support (8), a plurality of interfaces (4) are arranged on the blast oven (1), a syringe pump (10) is mounted on the outer side of the blast oven (1), a plurality of high-temperature-resistant and corrosion-resistant pipelines (11) are respectively in butt joint with corresponding interfaces (4), a display device (2) is mounted on the front side of the blast oven (1), a controller (3) is arranged on the outer side of the display device (2), and the controller (3) is mounted on the front side of the blast oven (1).
  2. 2. The full-process temperature-controllable instantaneous nano-sedimentation reaction device of claim 1 is characterized in that the adjustable movable plate support (8) is clamped on the inner wall of the blast oven (1).
  3. 3. The full-process temperature-controllable instantaneous nano-sedimentation reaction device according to claim 1, wherein the inner cavity of the blast oven (1) is embedded with a heat insulation layer (6), and the heat insulation layer (6) is made of a heat insulation material serving as a base material.
  4. 4. The full-process temperature-controllable instantaneous nano-sedimentation reaction device according to claim 1, wherein a box door (14) is movably arranged on the front side of the blast oven (1), and a handle (17) is arranged on the box door (14).
  5. 5. The full-process temperature-controllable instantaneous nano-sedimentation reaction device according to claim 4, wherein a door lock (16) is commonly installed between the box door (14) and the blast oven (1).
  6. 6. The full-process temperature-controllable instantaneous nano-sedimentation reaction device according to claim 4, wherein the box door (14) is provided with a transparent window (15).

Description

Full-flow temperature controllable instantaneous nano sedimentation reaction equipment Technical Field The utility model relates to the technical field of experimental equipment, in particular to full-process temperature-controllable instantaneous nano sedimentation reaction equipment. Background The instantaneous nano sedimentation technology (FNP) is an innovative technology for realizing the accurate preparation of nano materials based on an ultra-fast micro mixing mechanism. The core principle is that the micro-fluidic or collision jet technology is used for triggering the instantaneous and uniform mixing of reactant solutions, triggering the rapid self-assembly process and forming nano particles in millisecond time scale. By accurately regulating and controlling key parameters such as reactant concentration, temperature, mixing speed and the like, the precise control of the particle size, morphology structure and monodispersity of the product can be realized. In research in the fields of material science, chemistry, etc., FNP (transient nano sedimentation technique) experiments are widely applied to the preparation and research of various nano materials. However, the temperature conditions of the experiment have a crucial influence on the experimental results. Traditional experimental devices often have difficulty in accurately controlling experimental temperatures or cannot adapt to FNP experiments with different temperature requirements, so that the accuracy and repeatability of the experiments are limited. Therefore, the application provides a full-flow temperature-controllable instantaneous nano-sedimentation reaction device for solving the problems. Disclosure of utility model The utility model aims to provide full-process temperature-controllable instantaneous nano sedimentation reaction equipment so as to realize accurate control of experimental temperature, meet FNP experimental requirements under different temperature conditions, and improve reaction efficiency and product quality by accurately controlling reaction temperature and flow rate. In order to achieve the purpose, the technical scheme is that the full-flow temperature-controllable instant nano sedimentation reaction device comprises a blowing oven, wherein an inner cavity of the blowing oven is a heating cavity, a plurality of temperature sensors are uniformly distributed on the inner wall of the heating cavity, a plurality of heating wires are uniformly distributed on the inner wall of the heating cavity, an adjustable movable plate support is arranged on the inner wall of the heating cavity, an FNP (fiber reinforced polymer) reactor is arranged above the adjustable movable plate support, a plurality of interfaces are arranged on the blowing oven, an injector pump is arranged on the outer side of the blowing oven, a plurality of high-temperature-resistant corrosion-resistant pipelines are arranged on the injector pump, the high-temperature-resistant corrosion-resistant pipelines are respectively in butt joint with the corresponding interfaces, a display device is arranged on the front side of the blowing oven, and a controller is arranged on the outer side of the display device and is arranged on the front side of the blowing oven. Preferably, the adjustable movable plate support is clamped on the inner wall of the blast oven. Preferably, a heat insulation layer is embedded and installed in the inner cavity of the blast oven, and the heat insulation layer is made of a heat insulation material serving as a base material. Preferably, a box door is movably arranged on the front side of the blast oven, and a handle is arranged on the box door. Preferably, a door lock is commonly installed between the box door and the blast oven. Preferably, a transparent window is installed on the box door. Compared with the prior art, the utility model has the beneficial effects that: The application realizes FNP reaction under different temperature conditions by matching the components such as the blast oven, the temperature sensor and the like, ensures stable transmission of reactants under high temperature environment by designing a high temperature resistant corrosion resistant pipeline, is adjustable in injection speed of the injector pump, meets different experimental reaction rate requirements, further enhances flexibility and applicability of the device, and has the advantages of simple equipment structure, convenient operation, suitability for laboratory and small-scale production and good use effect. Drawings FIG. 1 is a schematic view of an external structure of the present utility model in an angle; FIG. 2 is a schematic view of the external structure of the present utility model at another angle; FIG. 3 is a schematic view of the internal planar structure of the present utility model; FIG. 4 is a schematic cross-sectional view of the present utility model; fig. 5 is a schematic view of the structure of the adjustable movable plate support