CN111151309A

CN111151309A - Chemical reaction case is used in protection that can self-cleaning

Info

Publication number: CN111151309A
Application number: CN202010102953.4A
Authority: CN
Inventors: 不公告发明人
Original assignee: Fuzhou Mawei Haoli Garment Co ltd
Current assignee: Fuzhou Mawei Haoli Garment Co ltd
Priority date: 2020-02-19
Filing date: 2020-02-19
Publication date: 2020-05-15
Also published as: GB202008223D0

Abstract

The invention discloses a protective chemical reaction box capable of being automatically cleaned, which comprises a box body, wherein an experiment cavity for chemical reaction is arranged in the box body, a reagent cavity for placing a chemical reagent is communicated with the lower wall of the experiment cavity, an input device is arranged on the upper side of the experiment cavity, a conveying cavity which is arranged on the upper side of the experiment cavity and is provided with a right opening is arranged in the input device, a conveying plate is arranged in the conveying cavity in a left-right sliding mode, and a storage cavity is arranged in the conveying plate in a vertically penetrating mode. The influence of residual chemical substances on the next reaction is avoided.

Description

Chemical reaction case is used in protection that can self-cleaning

Technical Field

The invention relates to the field of chemistry, in particular to a protective chemical reaction box capable of being automatically cleaned.

Background

Chemical experiments are important ways for researching and learning chemistry, many chemical reactions can produce violent reactions, safety threats are easily caused to experimenters, and particularly when unknown reaction experiments are carried out, protection and protection are extremely important. Some existing semi-closed experimental boxes only perform simple closed blocking, but still need manual reagent adding, still have dangerousness if the chemical reaction speed is too fast and too violent during adding, and need take out the reactant after the experiment is finished, and carry out manual cleaning to the experimental box in, it is extremely troublesome to use.

Disclosure of Invention

The invention aims to provide a protective chemical reaction box capable of being automatically cleaned, which is used for overcoming the defects in the prior art.

The protective chemical reaction box capable of being automatically cleaned comprises a box body, wherein an experiment cavity for chemical reaction is arranged in the box body, a reagent cavity for placing a chemical reagent is communicated with the lower wall of the experiment cavity, an input device is arranged on the upper side of the experiment cavity, a conveying cavity which is arranged on the upper side of the experiment cavity and has a right opening is arranged in the input device, a conveying plate is arranged in the conveying cavity in a left-right sliding mode, a storage cavity is arranged in the conveying plate in a vertically penetrating mode, a sealing plate capable of sealing the bottom of the storage cavity is arranged on the bottom of the right wall of the storage cavity in a left-right sliding mode, a dropping opening capable of being communicated with the lower side of the sealing plate is arranged between the lower wall of the conveying cavity and the upper wall of the experiment cavity in a communicating mode, when the conveying plate moves to the right, the sealing plate moves to the left relative to the storage cavity and seals the bottom of the storage cavity, an input pipeline which has an upward opening and is communicated with, a material taking cavity with a right opening is arranged at the lower right side of the reagent cavity, a sewage pipeline with a left opening is arranged at the lower left side of the reagent cavity, a switching and conducting device cleaning device is arranged between the lower side of the reagent cavity and the material taking cavity as well as between the lower side of the sewage pipeline, a switching plate capable of moving left and right is arranged in the switching and conducting device cleaning device, the switching plate can move left and right to discharge reaction products in the reagent cavity through the upper wall of the material taking cavity and the switching plate respectively, a cleaning device is arranged at the upper side of the conveying cavity, a water conveying cavity which is positioned at the upper side of the conveying cavity and is just opposite to the upper side of the storage cavity is arranged in the cleaning device, a water conveying pipeline communicated with the right wall of the input pipeline is arranged at the upper side of the water conveying cavity, a valve plate is arranged at the opening at the rear end of the water conveying pipeline and, when the valve plate opens the water pipeline, the sliding pipeline moves forwards.

According to the technical scheme, the input device comprises a communicating baffle cavity arranged at the bottom end of the right wall of the storage cavity, the sealing plate slides left and right in the baffle cavity, a guide chute with a downward opening is formed in the lower side of the baffle cavity in a communicating mode, a guide block connected with the inner wall of the guide chute in a sliding mode is fixedly arranged at the right end of the lower end face of the sealing plate, a fixed block capable of abutting against the left end face of the guide block is fixedly arranged on the lower wall of the conveying cavity, and the right wall of the storage cavity is located on the upper side of the baffle cavity in a communicating mode and provided with a slope cavity with an upward opening and a low.

According to the further technical scheme, a compression spring is fixedly connected between the right end of the sealing plate and the right wall of the baffle cavity.

According to the technical scheme, the rear wall of the conveying cavity is communicated with a sliding cavity, a sliding block fixedly connected to the rear end face of the conveying plate is connected in the sliding cavity in a left-right sliding mode, a conveying motor is fixedly arranged in the right wall of the sliding cavity, and the left end of the conveying motor is in power connection with a conveying screw in the sliding block in a threaded mode.

According to the technical scheme, the switching conduction device comprises a switching cavity communicated with the lower wall of the reagent cavity, the switching plate slides left and right in the switching cavity, a communicating pipeline capable of being communicated with the lower side of the reagent cavity is arranged in the switching plate in a vertical penetrating mode, the lower end of the communicating pipeline inclines towards the center of the away symmetry, a discharging port which is opposite to the lower side of the communicating pipeline and is respectively arranged on the left side and the right side of the communicating pipeline and has the same slope is arranged in the switching plate in a bilateral symmetrical mode, the lower end of the discharging port is communicated with the upper wall of the material taking cavity, and the lower end of the discharging port is communicated with the right wall of the sewage discharging pipeline.

According to the further technical scheme, a control cavity is communicated with the rear side of the switching cavity, a control block fixedly connected to the rear end of the switching plate is arranged in the control cavity in a left-right sliding mode, a control motor is fixedly arranged in the right wall of the control cavity, and the left end of the control motor is in power connection with a valve control screw rod in threaded connection with the control block.

According to a further technical scheme, the cleaning device comprises a nozzle which is communicated and arranged between the lower wall of the water delivery cavity and the upper wall of the delivery cavity, a branch opening is communicated and arranged between the upper wall of the water delivery cavity and the water delivery pipeline, a sliding pipeline is arranged between the front wall and the rear wall of the vertical part at the rear side of the water delivery pipeline in a penetrating mode, the valve plate is arranged in the sliding pipeline in a sliding mode, and a communication opening which can be communicated with the water delivery pipeline is arranged in the valve plate in a penetrating mode from top to bottom.

According to the technical scheme, a pipeline sliding cavity with a backward opening is formed in the rear wall of the material taking cavity in a communicating mode, the sliding pipeline is arranged in the pipeline sliding cavity in a sliding mode, the front end of the sliding pipeline is bent upwards and abuts against the upper wall of the material taking cavity, and a discharge pipeline capable of being communicated with the lower end of the discharge port is arranged in the sliding pipeline in a penetrating mode.

Further technical scheme, pipeline slip chamber upper wall intercommunication be equipped with communicate in the translation chamber of slip pipeline rear side, gliding the being equipped with translation board around the translation intracavity, translation board lower extreme fixed connection in the slip pipeline upper end, valve plate rear end fixed connection in terminal surface upper end before the translation board, translation intracavity antetheca internal fixation is equipped with translation motor, translation motor rear end power connection have threaded connection in translation screw rod in the translation board.

According to the technical scheme, transparent glass is fixedly arranged between the inner portion of the right wall of the experimental cavity and the inner portion of the right end face of the box body and is used for observing the reaction condition of the experimental cavity and the reaction condition of the reagent cavity.

The invention has the beneficial effects that: the semi-sealed experimental cavity is used for conveying solid chemical substances and liquid chemical substances into the semi-sealed experimental cavity separately for reaction, so that the damage of violent reaction generated in the reaction on a human body is avoided, the safety is high, the substances generated in the reaction can be taken out according to the requirement, the reactants are taken out or directly discharged, all places contacting with the chemical substances can be washed by water after the reaction, and the influence of the residual chemical substances on the next reaction is avoided.

Drawings

FIG. 1 is a schematic view showing the internal structure of an apparatus for a self-cleaning chemical reaction chamber for protection according to the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" in FIG. 1;

FIG. 4 is an enlarged schematic view of the structure of "C" in FIG. 1;

FIG. 5 is a schematic view of the structure in the direction "D-D" in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 5, the protective chemical reaction box capable of being automatically cleaned according to the embodiment of the present invention includes a box body 11, an experiment chamber 12 for chemical reaction is provided in the box body 11, a reagent chamber 13 for placing a chemical reagent is provided in the lower wall of the experiment chamber 12 in a communicating manner, an input device 101 is provided on the upper side of the experiment chamber 12, a conveying chamber 14 provided on the upper side of the experiment chamber 12 and having a right opening is provided in the input device 101, a conveying plate 15 is provided in the conveying chamber 14 in a left-right sliding manner, a storage chamber 16 is provided in the conveying plate 15 in a vertically penetrating manner, a sealing plate 17 capable of sealing the bottom of the storage chamber 16 is provided in the bottom of the right wall of the storage chamber 16 in a left-right sliding manner, a dropping port 18 capable of communicating with the lower side of the sealing plate 17 is provided between the lower wall of the conveying chamber 14 and the upper wall of the experiment chamber 12, when the conveying plate 15 moves to the right, the sealing plate 17 moves to, an input pipeline 22 with an upward opening and used for inputting test solution is communicated with the left side of the conveying cavity 14 and arranged on the upper wall of the experiment cavity 12, a material taking cavity 19 with a rightward opening is arranged on the lower right side of the reagent cavity 13, a sewage pipeline 20 with a leftward opening is arranged on the lower left side of the reagent cavity 13, a switching and conducting device cleaning device 103 is arranged between the lower side of the reagent cavity 13 and the material taking cavity 19 and between the lower side of the sewage pipeline 20, a switching plate 21 capable of moving left and right is arranged in the switching and conducting device cleaning device 103, the switching plate 21 can move left and right to discharge reaction products in the reagent cavity 13 through the upper wall of the material taking cavity 19 and the switching plate 21 respectively, a cleaning device 103 is arranged on the upper side of the conveying cavity 14, a water conveying cavity 23 which is positioned on the upper side of the conveying cavity 14 and is opposite to the upper side of the storage cavity 16 is arranged in the cleaning device 103, and a water conveying pipeline 24 communicated with the right, the rear end of the water pipeline 24 is opened upwards, a valve plate 25 is arranged between the front wall and the rear wall in a sliding mode, a sliding pipeline 26 is arranged on the rear wall of the material taking cavity 19 in a sliding mode, and when the water pipeline 24 is opened through the valve plate 25, the sliding pipeline 26 moves forwards.

Beneficially, the input device 101 includes a baffle cavity 27 communicated with the bottom end of the right wall of the storage cavity 16, the sealing plate 17 is arranged in the baffle cavity 27 in a left-right sliding manner, a guide chute 28 with a downward opening is communicated with the lower side of the baffle cavity 27, a guide slider 29 connected with the inner wall of the guide chute 28 in a left-right sliding manner is fixedly arranged at the right end of the lower end face of the sealing plate 17, a fixed block 30 capable of abutting against the left end face of the guide slider 29 is fixedly arranged at the lower wall of the conveying cavity 14, and a slope cavity 31 with an upward opening and a low left and high right is communicated with the upper side of the baffle cavity 27 on the right wall of the storage cavity 16.

Advantageously, a compression spring 32 is fixedly connected between the right end of the sealing plate 17 and the right wall of the baffle cavity 27, and the compression spring 32 provides power for the left movement of the sealing plate 17.

Advantageously, a sliding cavity 33 is communicated with the rear wall of the conveying cavity 14, a sliding block 34 fixedly connected to the rear end surface of the conveying plate 15 is slidably connected to the sliding cavity 33 from left to right, a conveying motor 35 is fixedly arranged in the right wall of the sliding cavity 33, and a conveying screw 36 threadedly connected to the sliding block 34 is dynamically connected to the left end of the conveying motor 35.

Beneficially, the switching conduction device 102 includes a switching chamber 37 communicated with the lower wall of the reagent chamber 13, the switching plate 21 is disposed in the switching chamber 37 in a left-right sliding manner, a communicating pipe 38 capable of being switched and communicated with the lower side of the reagent chamber 13 is disposed in the switching plate 21 in a left-right symmetrical manner and vertically penetrating therethrough, the lower end of the communicating pipe 38 is inclined away from the symmetrical center, the lower wall of the switching chamber 37 is provided with discharge ports 39 which are opposite to the lower side of the communicating pipe 38 and have the same slope with the communicating pipes 38 on the left and right sides, the lower end of the discharge port 39 on the right side is communicated with the upper wall of the material taking chamber 19, and the lower end of the discharge port 39 on the left side is communicated with the.

Advantageously, a control cavity 40 is communicated with the rear side of the switching cavity 37, a control block 41 fixedly connected to the rear end of the switching plate 21 is slidably arranged in the control cavity 40 from left to right, a control motor 42 is fixedly arranged in the right wall of the control cavity 40, and a valve control screw 43 which is in threaded connection with the control block 41 is dynamically connected to the left end of the control motor 42.

Beneficially, the cleaning device 103 includes a nozzle 44 which is communicated between the lower wall of the water delivery cavity 23 and the upper wall of the delivery cavity 14, a diversion port 45 is communicated between the upper wall of the water delivery cavity 23 and the water delivery pipe 24, a sliding pipe 46 is arranged between the front wall and the rear wall of the vertical portion at the rear side of the water delivery pipe 24 in a penetrating manner, the valve plate 25 is arranged in the sliding pipe 46 in a sliding manner, and a communication port 47 which can be communicated with the water delivery pipe 24 is arranged in the valve plate 25 in a penetrating manner up and down.

Advantageously, a pipeline sliding cavity 48 with a backward opening is arranged in the rear wall of the material taking cavity 19 in a communicating manner, the sliding pipeline 26 is arranged in the pipeline sliding cavity 48 in a sliding manner back and forth, the front end of the sliding pipeline 26 is bent upwards and is abutted against the upper wall of the material taking cavity 19, and a discharge pipeline 49 capable of communicating with the lower end of the right discharge port 39 is arranged in the sliding pipeline 26 in a passing manner.

Beneficially, the upper wall of the pipeline sliding cavity 48 is communicated with a translation cavity 50 communicated with the rear side of the sliding pipeline 46, a translation plate 51 is arranged in the translation cavity 50 and slides back and forth, the lower end of the translation plate 51 is fixedly connected to the upper end of the sliding pipeline 26, the rear end of the valve plate 25 is fixedly connected to the upper end of the front end face of the translation plate 51, a translation motor 52 is fixedly arranged in the front wall of the translation cavity 50, and the rear end of the translation motor 52 is dynamically connected with a translation screw 53 in threaded connection with the translation plate 51.

Beneficially, a transparent glass 54 is fixedly arranged between the right wall of the experiment cavity 12 and the right end face of the box body 11, and the transparent glass 54 is used for observing the reaction condition of the experiment cavity 12 and the reagent cavity 13.

In the initial state, the conveying plate 15 is located at the left limit position, the sealing plate 17 is retracted in the baffle cavity 27 and compresses the compression spring 32, the switching plate 21 is located at the middle position and seals the bottom of the reagent cavity 13, the valve plate 25 is located at the rear limit position and seals the water conveying pipeline 24, the sliding pipeline 26 is located at the rear limit position and located at the rear side of the right side discharge port 39, and the guide sliding block 29 is abutted against the fixed block 30.

During the experiment, the conveying motor 35 is started and drives the conveying screw 36 to rotate, the sliding block 34 is driven to move right through threaded connection, the conveying plate 15 is driven to move right to the inclined surface cavity 31 and move out of the conveying cavity 14, the sealing plate 17 moves left relative to the baffle cavity 27 under the elasticity of the compression spring 32 and seals the bottom of the storage cavity 16, a solid chemical to be added is placed in the inclined surface cavity 31 and slides into the storage cavity 16, the conveying plate 15 is reset at the moment, the solid chemical in the storage cavity 16 falls into the reagent cavity 13 through the falling port 18, other solid chemicals are conveyed into the reagent cavity 13 to react according to the same method, the liquid chemical can be conveyed into the reagent cavity 13 through the input pipeline 22, the reaction phenomenon is observed according to substances to be reacted, after the reaction is finished, if the reactants need to be taken out for observation, the container can be placed on the lower wall of the material taking cavity 19, at this time, the front end of the control motor 42 drives the valve control screw 43 to rotate, the control block 41 is connected with threads and the control block is moved to the left, the switching plate 21 is driven to move to the left, the right communicating pipeline 38 is communicated with the right discharging port 39, reactants in the reagent cavity 13 fall into the material taking cavity 19 through the right communicating pipeline 38 and the discharging port 39, and then fall into the container, when the reactants are directly discharged, the control motor 42 reversely rotates to drive the switching plate 21 to move to the right, the left communicating pipeline 38 communicates the reagent cavity 13 with the left discharging port 39, the reactants in the reagent cavity 13 are directly discharged through the left communicating pipeline 38, the discharging port 39 and the sewage discharge pipeline 20, when cleaning is needed, the translation motor 52 is started and drives the translation screw 53 to rotate, the translation plate 51 is driven to move forward through threaded connection, and then the valve plate 25 and the sliding, the valve plate 25 moves forwards and communicates the communicating port 47 with the water conveying pipeline 24, the sliding pipeline 26 moves forwards to communicate the front end of the discharge pipeline 49 with the bottom of the right side discharge port 39, at the moment, water flows into the input pipeline 22 through the water conveying pipeline 24 to wash the inner wall of the input pipeline 22 and gild the experiment cavity 12 and the reagent cavity 13, part of the water in the water conveying pipeline 24 is input into the water conveying cavity 23 through the diversion port 45, the inner wall of the storage cavity 16 is washed through the nozzle 44 and flows into the experiment cavity 12 and the reagent cavity 13 through the falling port 18, the switching plate 21 is controlled to move left, and then sewage in the reagent cavity 13 is input into the discharge pipeline 49 through the right side communicating pipeline 38 and the discharge port 39 and is discharged.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. The utility model provides a but chemical reaction case is used in self-cleaning's protection, includes the box, its characterized in that: an experimental cavity for chemical reaction is arranged in the box body, a reagent cavity for placing chemical reagents is communicated with the lower wall of the experimental cavity, an input device is arranged on the upper side of the experimental cavity, a conveying cavity which is arranged on the upper side of the experimental cavity and has a rightward opening is arranged in the input device, a conveying plate is arranged in the conveying cavity in a left-right sliding manner, a storage cavity is arranged in the conveying plate in a vertical penetrating manner, a sealing plate capable of sealing the bottom of the storage cavity is arranged at the bottom of the right wall of the storage cavity in a left-right sliding manner, a dropping opening capable of being communicated with the lower side of the sealing plate is arranged between the lower wall of the conveying cavity and the upper wall of the experimental cavity in a communicating manner, when the conveying plate moves rightwards, the sealing plate moves leftwards relative to the storage cavity and seals the bottom of the storage cavity, an input pipeline with an upward opening is communicated with the left side of the conveying cavity and used for inputting test solution, and, a sewage pipeline with a leftward opening is arranged on the lower left side of the reagent cavity, a switching and conducting device cleaning device is arranged between the lower side of the reagent cavity and the material taking cavity as well as between the lower side of the reagent cavity and the upper side of the sewage pipeline, a switching plate capable of moving left and right is arranged in the switching and conducting device cleaning device, the switching plate can move left and right to discharge reaction products in the reagent cavity through the upper wall of the material taking cavity and the switching plate respectively, a cleaning device is arranged on the upper side of the conveying cavity, a water conveying cavity which is positioned on the upper side of the conveying cavity and is just opposite to the upper side of the storage cavity is arranged in the cleaning device, a water conveying pipeline communicated with the right wall of the input pipeline is arranged on the upper side of the water conveying cavity, a valve plate is arranged on the rear end of the water conveying pipeline in an upward manner and in a manner that the front, the sliding duct is advanced.

2. The protective chemical reaction box capable of being automatically cleaned according to claim 1, wherein the input device comprises a baffle cavity communicated with the bottom end of the right wall of the storage cavity, the sealing plate is arranged in the baffle cavity in a left-right sliding manner, a guide chute with a downward opening is communicated with the lower side of the baffle cavity, a guide block connected with the inner wall of the guide chute in a left-right sliding manner is fixedly arranged at the right end of the lower end surface of the sealing plate, a fixed block capable of abutting against the left end surface of the guide block is fixedly arranged at the lower wall of the conveying cavity, and a slope cavity with an upward opening and a low left and a high right is communicated with the upper side of the baffle cavity of the right wall of the storage cavity.

3. The self-cleaning chemical reaction chamber for protection as claimed in claim 1, wherein a compression spring is fixedly connected between the right end of the sealing plate and the right wall of the baffle chamber.

4. The chemical reaction box for protection purpose of claim 2, wherein the back wall of the conveying cavity is communicated with a sliding cavity, a sliding block fixedly connected to the back end surface of the conveying plate is connected in the sliding cavity in a left-right sliding manner, a conveying motor is fixedly arranged in the right wall of the sliding cavity, and the left end of the conveying motor is dynamically connected with a conveying screw rod in threaded connection with the sliding block.

5. The chemical reaction box for protection purpose of claim 1, wherein the switching device comprises a switching chamber communicated with the lower wall of the reagent chamber, the switching plate is slidably disposed in the switching chamber, communicating pipes capable of being switched and communicated with the lower side of the reagent chamber are symmetrically disposed in the switching plate from left to right and vertically penetrate through the switching plate, the lower ends of the communicating pipes are inclined away from the center of symmetry, the lower wall of the switching chamber is symmetrically disposed in the left to right and is communicated with outlet ports, the outlet ports are opposite to the lower side of the communicating pipes and have the same slope with the communicating pipes on the left and right sides, the lower end of the outlet port on the right side is communicated with the upper wall of the material taking chamber, and the lower end of the outlet port on the left side is communicated.

6. The chemical reaction box for protection purpose of claim 5, wherein a control chamber is communicated with the rear side of the switching chamber, a control block fixedly connected to the rear end of the switching plate is slidably arranged in the control chamber from side to side, a control motor is fixedly arranged in the right wall of the control chamber, and the left end of the control motor is dynamically connected with a valve control screw rod in threaded connection with the control block.

7. The protective chemical reaction box capable of being automatically cleaned according to claim 1, wherein the cleaning device comprises a nozzle communicated between the lower wall of the water delivery cavity and the upper wall of the delivery cavity, a branch port is communicated between the upper wall of the water delivery cavity and the water delivery pipeline, a sliding pipeline is arranged between the front wall and the rear wall of the vertical part at the rear side of the water delivery pipeline in a penetrating manner, the valve plate is arranged in the sliding pipeline in a sliding manner, and a communication port capable of being communicated with the water delivery pipeline is arranged in the valve plate in a penetrating manner from top to bottom.

8. The chemical reaction box for protection purpose of claim 7, wherein a pipeline sliding cavity with a backward opening is communicated with the rear wall of the material taking cavity, the sliding pipeline is slidably arranged in the pipeline sliding cavity back and forth, the front end of the sliding pipeline is bent upwards and is abutted against the upper wall of the material taking cavity, and a discharge pipeline capable of being communicated with the lower end of the right discharge port is arranged in the sliding pipeline in a penetrating manner.

9. The protective chemical reaction box capable of being automatically cleaned according to claim 8, wherein a translation cavity communicated with the rear side of the sliding pipeline is communicated with the upper wall of the pipeline sliding cavity, a translation plate is arranged in the translation cavity in a front-back sliding manner, the lower end of the translation plate is fixedly connected to the upper end of the sliding pipeline, the rear end of the valve plate is fixedly connected to the upper end of the front end face of the translation plate, a translation motor is fixedly arranged in the front wall of the translation cavity, and a translation screw rod in threaded connection with the translation plate is dynamically connected to the rear end of the translation motor.

10. The chemical reaction box capable of being automatically cleaned for protection as claimed in claim 1, wherein a transparent glass is fixedly arranged between the inner part of the right wall of the experiment cavity and the inner part of the right end face of the box body.