CN117706222B - Automatic preassembling test platform for reactor production - Google Patents

Abstract

The invention discloses an automatic preassembling test platform for reactor production, which relates to the technical field of reactor production and comprises a test platform mechanism, wherein a processing mechanism is arranged on the test platform mechanism, the processing mechanism comprises rectangular holes, two round tubes, a water storage tank, two air guide holes, a storage tank and a sealing plate, electric push rods are arranged in the two round tubes, a fan is arranged on the upper side of the inside of the storage tank, a drying layer is arranged in the shell, an adsorption layer is arranged at the top of the drying layer, a liquid storage box is arranged at the bottom of the inner wall of the storage tank, and a one-way valve is arranged at the input end of the L-shaped tube.

Description

Automatic preassembling test platform for reactor production

Technical Field

The invention relates to the technical field of reactor production, in particular to an automatic preassembling test platform for reactor production.

Background

The reactor is also called an inductor, has wide application in a circuit, has a certain inductive property because of the electromagnetic induction effect in the circuit, and can play a role in preventing current change, and in order to ensure production quality in the production process of the existing reactor, the reactor is preloaded and tested by an automatic preloaded test platform in the production process of the reactor.

In the prior art, although the automatic preassembling test platform for reactor production can test the quality of the reactor in the production process in the actual use process, the manufactured reactor can be normally used, but the reactor has no emergency treatment function, when the reactor suddenly has a short circuit in the preassembling test process, the parts inside the reactor can generate overload and heat and burn and emit certain harmful gas, if the reactor with problems cannot be timely treated, the harmful gas emitted by the reactor can be emitted into a test room where a detector is located, and the detector can influence the physical health of the detector when inhaling the harmful gas, namely, the use efficiency of the automatic preassembling test platform for reactor production is reduced.

Therefore, a new automated preassembly test platform for reactor production needs to be proposed so as to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide an automatic preassembly test platform for reactor production, which aims to solve the problems that the existing automatic preassembly test platform for reactor production in the prior art does not have an emergency treatment function, when a short circuit happens suddenly in the process of preassembling the reactor, overload heating combustion occurs on parts in the reactor at the moment, certain harmful gas is emitted, and if the reactor with problems cannot be treated in time, the harmful gas emitted by the reactor can be emitted into a test room where a detector is located, so that the physical health of the detector is influenced, and the use efficiency of the automatic preassembly test platform for reactor production is reduced.

In order to achieve the above purpose, the present invention provides the following technical solutions: the automatic preassembling test platform for the production of the reactor comprises a test platform mechanism, wherein a processing mechanism is arranged on the test platform mechanism;

The utility model provides a processing mechanism includes rectangular hole, two pipes, aqua storage tank, two air-guide holes, storing groove and closing plate, the inside of rectangular hole is provided with the movable plate, two symmetrical link is installed to the bottom of movable plate, two electric putter is all installed to the inside of pipe, two the inside of air-guide hole is close to the equal fixed intake pipe that has cup jointed of input, two the breathing pipe is all installed to the input of intake pipe, two the inside of air-guide hole is close to the equal fixed outlet duct that has cup jointed of output, two install the tee bend between the output of outlet duct, the fan is installed to the inside upside of storing groove, the inner wall bottom of storing groove is provided with the casing, the inside of casing is close to the bottom position and is provided with porous placing table, the inside of casing is provided with the dry layer, the top of dry layer is provided with the adsorbed layer, the top of casing is installed, the first trachea is installed to the output of cap, the inner wall bottom of storing groove is provided with the receiver, inner wall one side of receiver is fixed with L pipe, L pipe is installed to the output, the second fan is installed to the output.

Preferably, the bottoms of the telescopic ends of the two electric push rods are respectively installed on the upper sides of the two connecting frames through first screws, the input end of the fan is connected with the output end of the three-way pipe, the drying layer and the adsorption layer are both positioned in the shell, the input end of the L-shaped pipe is close to the bottom position of the inner wall of the shell, the input end of the one-way valve is connected with the output end of the first air pipe, the output end of the second air pipe is connected with the air inlet end of the shell, the outlet of the rectangular hole is communicated with the top of the inner wall of the water storage tank, and the top of the air suction pipe is fixed with the top of the inner wall of the water storage tank.

Preferably, the screw thread at the top of the inner wall of the storage tank is penetrated with an electric valve, the input end of the electric valve is communicated with the bottom of the inner wall of the water storage tank, and the top of the input end of the electric valve and the bottom of the inner wall of the water storage tank are positioned on the same horizontal plane.

Preferably, the test platform mechanism comprises a workbench and a bottom plate, the rectangular hole is formed in the top of the workbench, the water storage tank is formed in the front surface of the workbench, the bottoms of the two round tubes are fixed on the top of the workbench, the telescopic ends of the two electric push rods movably penetrate through the top of the workbench, and the telescopic ends of the two electric push rods extend to the inside of the water storage tank.

Preferably, two air guide holes are formed between one side of the inner wall of the water storage tank and one side of the inner wall of the storage tank, the sealing plate is mounted on the front surface of the workbench through bolts, an L-shaped block is fixed at the top of the workbench, a first placement hole is formed in the front surface of the workbench, a rectangular grid plate is fixed in the first placement hole, a storage battery is arranged at the top of the rectangular grid plate, and a second placement hole is formed in the front surface of the L-shaped block close to the rear side.

Preferably, the display screen is arranged in the second placing hole, the fixing frame is arranged in the second placing hole near the inlet, the front surface of the display screen is in contact with the surface of the fixing frame, the rectangular groove is formed in the upper side of the L-shaped block, the controller is arranged in the rectangular groove, and the wire arrangement hole is formed between the inner wall of the rectangular groove and the bottom of the inner wall of the second placing hole.

Preferably, the top of workstation is fixed with places the box, the open-top department of placing the box is provided with the lid, crocodile clamp wire is all installed to two ports of controller, and the clamping end of two crocodile clamp wires all is in the inside of placing the box, the bottom plate passes through the second screw and installs at the top of movable plate, the top of workstation is fixed with the haplopore piece.

Preferably, the internally mounted of single hole piece has infrared temperature sensor, battery and controller electric connection, display screen and controller electric connection, infrared temperature sensor and controller electric connection, two electric putter all with controller electric connection, fan and controller electric connection, motorised valve and controller electric connection, the top of bottom plate is fixed with two symmetrical hollow blocks.

Preferably, two the inside of hollow piece all is provided with L shape pole, two the top of bottom plate all is fixed with the stopper, and two L shape poles respectively with two stopper recess looks adaptations, two the relative one end of L shape pole all is connected with the rectangular plate through the bearing rotation, and the bottom of two rectangular plates all contacts with the top of bottom plate, two the relative one side of rectangular plate all bonds and is connected with the cushion.

Preferably, the inner wall of the first placement hole is close to the inlet and is rotationally connected with a cover plate through a hinge, the position, close to one side, of the front surface of the cover plate is fixed on one side of the inner wall of the first placement hole through a manual lock, a first cylindrical hole is formed between one side of the inner wall of the storage groove and the inner wall of the first placement hole, a sealing ring is arranged in the first cylindrical hole, a second cylindrical hole is formed in the top of the inner wall of the first placement hole, and the opening of the second cylindrical hole is communicated with the opening of the wire arrangement hole.

Compared with the prior art, the invention has the beneficial effects that:

1. According to the invention, the short-circuited reactor can be treated in time by arranging the treatment mechanism, so that harmful gas is prevented from being scattered into a monitoring room where a detector is located, the physical health of the detector is ensured, namely, the use efficiency of an automatic preassembled test platform for reactor production is improved.

2. According to the invention, carbon monoxide, carbon dioxide, benzene and aldehydes in harmful gas can be adsorbed and removed by utilizing the cooperation of the first air pipe, the shell, the drying layer and the drying layer, and meanwhile, water vapor is dried, and then, hydrogen cyanide and hydrogen sulfide in the gas can be removed by utilizing the cooperation of the second air pipe, the one-way valve, the L-shaped pipe and the liquid storage box, so that the harmful gas is prevented from being emitted into a monitoring room where a detector is located.

3. According to the invention, the quality test operation can be performed on the reactor by arranging the test platform mechanism, when the preassembly test operation is required on the reactor, the reactor to be detected can be fixed on the bottom plate by utilizing the matching of the L-shaped rod, the limiting block, the hollow block, the rectangular plate and the soft cushion, then the electric parameter test and the temperature test can be performed on the reactor by utilizing the matching of the controller, the crocodile clamp wire, the display screen, the infrared temperature sensor and the storage battery, and the detected data can be displayed on the display screen.

Drawings

Fig. 1 is a perspective view of an automated preassembled test platform for reactor production according to the present invention;

fig. 2 is a partial perspective view of an automated preassembled test platform for reactor production according to the present invention;

Fig. 3 is a schematic diagram of a front view angle part structure of an automatic preassembly test platform for reactor production according to the present invention;

Fig. 4 is a partial perspective view of a processing mechanism of an automated preassembled test platform for reactor production according to the present invention;

fig. 5 is a perspective view, partially in section, of an automated pre-load test platform for reactor production in accordance with the present invention;

Fig. 6 is a partially cut-away perspective view of a handling mechanism of an automated pre-load test platform for reactor production in accordance with the present invention;

fig. 7 is a top view perspective view of a portion of an automated preassembled test platform for reactor production according to the present invention;

Fig. 8 is a perspective view of an air suction pipe of an automatic preassembled test platform for reactor production according to the invention;

fig. 9 is another perspective view of an alternative angle portion of an automated preassembled test platform for reactor production according to the present invention;

fig. 10 is a schematic diagram of a perspective structure of a second placement hole, a rectangular slot, and a flat cable hole of an automated preassembly test platform for reactor production according to the present invention;

Fig. 11 is a bottom perspective view of a portion of an automated preassembled test platform for reactor production according to the present invention;

fig. 12 is a perspective view of a rectangular grid plate of an automated preassembled test platform for reactor production according to the present invention.

In the figure: 1. a test platform mechanism; 101. a work table; 102. an L-shaped block; 103. a first placement hole; 104. rectangular grid plates; 105. a storage battery; 106. a second placement hole; 107. a display screen; 108. a fixed frame; 109. rectangular grooves; 110. a controller; 111. a wire arrangement hole; 112. placing a box; 113. a box cover; 114. crocodile clip wires; 115. a bottom plate; 116. a single hole block; 117. an infrared temperature measurement sensor; 118. a hollow block; 119. an L-shaped rod; 120. a limiting block; 121. a rectangular plate; 122. a soft cushion; 123. a cover plate; 124. a first cylindrical bore; 125. a seal ring; 126. a second cylindrical hole; 2. a processing mechanism; 201. a rectangular hole; 202. a moving plate; 203. a connecting frame; 204. an electric push rod; 205. a round tube; 206. a water storage tank; 207. an air suction pipe; 208. an air inlet pipe; 209. an air guide hole; 210. an air outlet pipe; 211. a storage tank; 212. a three-way pipe; 213. a blower; 214. a housing; 215. a multi-hole placement table; 216. drying the layer; 217. an adsorption layer; 218. a cover; 219. a first air tube; 220. a liquid storage box; 221. an L-shaped pipe; 222. a one-way valve; 223. a second air pipe; 224. a sealing plate; 225. an electric valve.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-12, the present invention provides a technical solution: an automatic preassembling test platform for reactor production comprises a test platform mechanism 1, wherein a processing mechanism 2 is arranged on the test platform mechanism 1;

The processing mechanism 2 comprises a rectangular hole 201, two round pipes 205, a water storage tank 206, two air guide holes 209, a storage tank 211 and a sealing plate 224, wherein a movable plate 202 is arranged in the rectangular hole 201, two symmetrical connecting frames 203 are arranged at the bottom of the movable plate 202, an electric push rod 204 is arranged at the top of the movable plate 202, an air inlet pipe 208 is fixedly sleeved at the inner positions of the two round pipes 205 close to the input ends, an air suction pipe 207 is arranged at the input ends of the two air inlet pipes 208, an air outlet pipe 210 is fixedly sleeved at the inner positions of the two air guide holes 209 close to the output ends, a three-way pipe 212 is arranged between the output ends of the two air outlet pipes 210, a fan 213 is arranged at the upper side of the inner part of the storage tank 211, a shell 214 is arranged at the bottom of the inner wall of the storage tank 211, a porous placing table 215 is arranged at the inner position of the inner part of the shell 214, a drying layer 216 is arranged at the top of the shell 214, an adsorption layer 217 is arranged at the top of the drying layer 216, a first air pipe 219 is arranged at the output end of the shell 218, a shell cover 220 is arranged at the inner wall bottom of the storage tank 211, a liquid storage box 220 is arranged at the inner wall of the storage box 220, a second air inlet pipe 221 is fixedly sleeved at the inner wall L221, and a second air inlet pipe 213 is fixedly penetrates through the L pipe 221, and a second air inlet pipe 223 is arranged at the inner wall of the storage box 220.

According to fig. 1-4, fig. 6 and fig. 7, the bottoms of the telescopic ends of the two electric push rods 204 are respectively installed on the upper sides of the two connecting frames 203 through first screws, the input end of the fan 213 is connected with the output end of the three-way pipe 212, the drying layer 216 and the adsorption layer 217 are both positioned inside the shell 214, the input end of the L-shaped pipe 221 is close to the bottom of the inner wall of the shell 214, the input end of the one-way valve 222 is connected with the output end of the first air pipe 219, the output end of the second air pipe 223 is connected with the air inlet end of the shell 214, the outlet of the rectangular hole 201 is communicated with the top of the inner wall of the water storage tank 206, the top of the air suction pipe 207 is fixed with the top of the inner wall of the water storage tank 206, and air in the water storage tank 206 can be sucked away conveniently under the action of the air suction pipe 207 and guided into the corresponding air inlet pipe 208.

According to fig. 2, 3 and 5, the top of the inner wall of the storage tank 211 is threaded through with an electric valve 225, the input end of the electric valve 225 is communicated with the bottom of the inner wall of the water storage tank 206, and the top of the input end of the electric valve 225 is on the same horizontal plane with the bottom of the inner wall of the water storage tank 206, so that the used liquid in the water storage tank 206 can be released under the action of the electric valve 225.

According to the embodiments shown in fig. 1-3, 5, 7 and 9, the test platform mechanism 1 includes a workbench 101 and a bottom plate 115, a rectangular hole 201 is formed at the top of the workbench 101, a water storage tank 206 is formed on the front surface of the workbench 101, a storage tank 211 is formed on the front surface of the workbench 101, the bottoms of two round tubes 205 are fixed at the top of the workbench 101, the telescopic ends of two electric push rods 204 are movably penetrated through the top of the workbench 101, and the telescopic ends of two electric push rods 204 extend to the inside of the water storage tank 206, so that the movable plate 202 can be driven to move up and down under the cooperation of the electric push rods 204, the round tubes 205 and the connecting frame 203.

According to the embodiments shown in fig. 1-3, 5, 9 and 12, two air guide holes 209 are formed between one side of the inner wall of the water storage tank 206 and one side of the inner wall of the storage tank 211, the sealing plate 224 is mounted on the front surface of the workbench 101 through bolts, the L-shaped block 102 is fixed on the top of the workbench 101, the first placement hole 103 is formed in the front surface of the workbench 101, the rectangular grid plate 104 is fixed in the first placement hole 103, the storage battery 105 is arranged on the top of the rectangular grid plate 104, the second placement hole 106 is formed in the position, close to the rear side, of the front surface of the L-shaped block 102, so that the display screen 107 is conveniently fixed on the L-shaped block 102 under the cooperation of the second placement hole 106 and the fixing frame 108.

According to the embodiment shown in fig. 1, 3, 9 and 10, the display screen 107 is disposed in the second placement hole 106, the fixing frame 108 is mounted in the second placement hole 106 near the inlet, the front surface of the display screen 107 contacts with the surface of the fixing frame 108, the rectangular slot 109 is formed on the upper side of the L-shaped block 102, the controller 110 is mounted in the rectangular slot 109, the flat cable hole 111 is formed between the inner wall of the rectangular slot 109 and the bottom of the inner wall of the second placement hole 106, and the controller 110 can be mounted on the L-shaped block 102 under the action of the rectangular slot 109.

According to the embodiments shown in fig. 1-3, 5, 7, 9 and 11, the placement box 112 is fixed on the top of the workbench 101, the box cover 113 is disposed at the top opening of the placement box 112, the crocodile clip wires 114 are installed at two ports of the controller 110, the clamping ends of the two crocodile clip wires 114 are located inside the placement box 112, the bottom plate 115 is installed on the top of the moving plate 202 through the second screw, the single hole block 116 is fixed on the top of the workbench 101, and the installation position can be provided for the infrared temperature measurement sensor 117 under the action of the single hole block 116, so that the reactor temperature measurement operation can be performed later.

According to the embodiments shown in fig. 1, 3, 4, 7 and 9, the infrared temperature sensor 117 is installed inside the single hole block 116, the battery 105 is electrically connected with the controller 110, the display screen 107 is electrically connected with the controller 110, the infrared temperature sensor 117 is electrically connected with the controller 110, the two electric push rods 204 are electrically connected with the controller 110, the fan 213 is electrically connected with the controller 110, the electric valve 225 is electrically connected with the controller 110, the top of the bottom plate 115 is fixed with two symmetrical hollow blocks 118, and the L-shaped rod 119 can be ensured to perform horizontal movement operation conveniently under the action of the hollow blocks 118.

According to the embodiment shown in fig. 1, fig. 3, fig. 9 and fig. 11, the inside of two hollow blocks 118 all is provided with L shape pole 119, and the top of two bottom plates 115 all is fixed with stopper 120, and two L shape poles 119 respectively with two stopper 120 recess looks adaptations, the relative one end of two L shape poles 119 all is connected with rectangular plate 121 through the bearing rotation, and the bottom of two rectangular plates 121 all contacts with the top of bottom plate 115, the relative one side of two rectangular plates 121 all is connected with soft pad 122 in an adhesive bonding way, can prevent that rectangular plate 121 from taking place friction loss when fixed reactor under the effect of soft pad 122.

According to fig. 1-3, 9 and 10, the inner wall of the first placement hole 103 is close to the inlet and is rotatably connected with a cover plate 123 through a hinge, the position of the front surface of the cover plate 123 close to one side is locked on one side of the inner wall of the first placement hole 103 through a manual lock, a first cylindrical hole 124 is formed between one side of the inner wall of the storage groove 211 and the inner wall of the first placement hole 103, a sealing ring 125 is arranged in the first cylindrical hole 124, a second cylindrical hole 126 is formed in the top of the inner wall of the first placement hole 103, the opening of the second cylindrical hole 126 is communicated with the opening of the flat cable hole 111, and the controller 110 can be electrically connected with the display screen 107 and the storage battery 105 respectively through cooperation of the second cylindrical hole 126.

The whole mechanism achieves the following effects: when the reactor needs to be pre-tested in the production process, firstly removing the sealing plate 224 from the workbench 101, then injecting a proper amount of clean water into the water storage tank 206, then injecting a proper amount of sodium hydroxide solution into the liquid storage box 220, then installing the sealing plate 224 back to the initial position, then opening the controller 110 by using the cooperation of the storage battery 105, setting a use program and a test program, setting the standard values of parameters of the test program, when the reactor is prepared together, directly opening the box cover 113 at the moment, then taking out the two crocodile clip wires 114 from the inside of the placement box 112, then the reactor to be tested is taken over, then the reactor is moved between the two soft cushions 122, then the two L-shaped rods 119 are moved in the same direction, when the two L-shaped rods 119 synchronously move, each L-shaped rod 119 moving at the moment directly drives the rectangular plate 121 to move under the cooperation of the corresponding hollow block 118, the two moving rectangular plates 121 directly drive the soft cushions 122 connected with the rectangular plate 121 to move, when the two rectangular plates 121 move to be unable to move, the two L-shaped rods 119 are directly rotated at the moment until the opposite ends of the two L-shaped rods 119 are respectively clamped inside the two limiting blocks 120, when the two L-shaped rods 119 complete the clamping operation, the reactor is already fixed, the two crocodile clamp wires 114 are clamped at two ends of the reactor, then the controller 110 is directly used for starting a test program to perform automatic test operation on the reactor, when the reactor is tested, the test program directly performs electrical parameter test on the reactor, the infrared temperature sensor 117 also monitors the temperature of the surface of the reactor at any time, the detected value is directly transmitted to the inside of the controller 110 in an electric signal mode after the detected value is obtained, the controller 110 directly compares the received temperature data with a parameter standard value set in advance by the controller 110, meanwhile, the electrical value detected by the controller 110 through the test program is also compared with the parameter standard value set in advance by the controller 110, when the temperature data received by the controller 110 and the electrical value detected by the controller 110 are both in the parameter standard value range set in advance by the controller 110, the quality of the reactor is qualified, the controller 110 directly transmits the detected data to the display screen 107 in an electric signal mode to display, and marks that the detected reactor quality is qualified, when the temperature data received by the controller 110 and the electrical value detected by the controller 110 are both higher than the parameter standard value set in advance by the controller 110, at this time, it is indicated that the internal elements of the tested reactor may be shorted, at this time, the controller 110 will also transmit the detected data to the display screen 107 directly in the form of an electrical signal, display the detected data, and mark that the detected reactor is unqualified, when the detecting personnel observe that the quality unqualified appearance appears on the display screen 107, the testing procedure is closed timely, and the two crocodile clamp wires 114 are removed from the reactor timely, at the same time, the internal elements of the reactor will also generate overload heat and burn due to the short circuit, and emit harmful gases (carbon monoxide, carbon dioxide, hydrogen cyanide, benzene, aldehydes and hydrogen sulfide), when the two crocodile clamp wires 114 are removed from the reactor, when the electric push rods 204 and the fans 213 are directly and synchronously started by the controller 110 when the electric push rods 204 and the fans 213 are put back into the placing box 112, the two electric push rods 204 started at the moment directly drive the connecting frames 203 connected with the electric push rods to move downwards under the cooperation of the corresponding round tubes 205, the two moving connecting frames 203 directly drive the moving plates 202 to move downwards together to move out of the rectangular holes 201, the moving plates 202 simultaneously drive the reactors fixed on the bottom plate 115 to move downwards, when the bottom plate 115 moves to be unable to move, the controller 110 directly and synchronously closes the two electric push rods 204 at the moment, the bottom plate 115 and the reactor fixed on the bottom plate 115 are directly immersed in water, that is, the overload of the reactor can be effectively avoided through water to burn, gas emission of the reactor is prevented, and before the reactor stops gas emission, partial gas (carbon dioxide, hydrogen cyanide, aldehyde substances and hydrogen sulfide) is dissolved in the water, but carbon monoxide gas and benzene gas in harmful gas can be emitted out of the water, meanwhile, the started fan 213 is matched with the tee 212, the two air outlet pipes 210, the two air guide holes 209 and the two air inlet pipes 208, so that suction force is directly obtained by each suction hole on the two air suction pipes 207, when the reactor for emitting the harmful gas passes through the two air suction pipes 207, the two air suction pipes 207 directly suck the harmful gas emitted by the reactor in the water storage tank 206, carbon monoxide gas, water vapor and benzene gas emitted from water, then the gas fed into the two air suction pipes 207 respectively enters the air inlet pipes 208 connected with the reactor, then the gas fed into the two air suction pipes 207 is directly fed into the corresponding air guide holes 209, then fed into the corresponding air outlet pipes 210, then fed and collected into the three-way pipe 212, and then matched by the fan 213, directly guiding the gas into the shell 214, then allowing the gas entering the shell 214 to directly enter the drying layer 216 (13X zeolite molecular sieve), directly removing water vapor mixed in the gas when the gas passes through the drying layer 216, simultaneously adsorbing and removing part of carbon monoxide, benzene, carbon dioxide, cyanide, acid gas, aldehydes and other gases in harmful gases, directly entering the adsorption layer 217 (activated carbon), and allowing the dried gas to directly enter the adsorption layer 217, wherein carbon monoxide, benzene, formaldehyde and other gases in the gas when the gas passes through the adsorption layer 217, The carbon dioxide, cyanide, acid gas, aldehydes and other gases are all adsorbed and removed, hydrogen cyanide and hydrogen sulfide in the gases are directly floated towards the inlet of the shell cover 218, then the hydrogen cyanide and the hydrogen sulfide directly enter the first gas pipe 219, then enter the check valve 222, then enter the L-shaped pipe 221, and then are directly guided into sodium hydroxide solution, when the hydrogen cyanide and the hydrogen sulfide are contacted with the sodium hydroxide solution, the hydrogen cyanide and the hydrogen sulfide respectively react with the sodium hydroxide solution at the moment, sodium cyanide and water are generated, namely, the neutralization and the removal of the hydrogen cyanide and the hydrogen sulfide are completed, after the reactor is soaked in the water for a period of time, at this time, the reactor fixed on the bottom plate 115 is reset to the initial position by directly using the cooperation of the controller 110, the moving plate 202, the connecting frame 203 and the two electric pushers 204, when the reactor is reset to the initial position, the two electric pushers 204 are directly turned off by using the controller 110, then the fan 213 is turned off, then the reactor is removed from the bottom plate 115, when the liquid in the water storage tank 206 needs to be discharged, the pipe input end for conveying the liquid is directly connected with the output end of the electric valve 225, then the electric valve 225 is opened by using the controller 110, when the electric valve 225 is opened, at this time, the used liquid in the water storage tank 206 directly flows into the electric valve 225, then flows into the pipe, is discharged, and finally closes the controller 110, thus completing the preassembly test operation of the reactor.

The storage battery 105, the display screen 107, the controller 110 (PLC controller), the crocodile clip wire 114, the infrared temperature sensor 117, the electric push rod 204, the fan 213, the drying layer 216, the adsorption layer 217, the check valve 222 and the electric valve 225 are all of the prior art, and will not be explained herein.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (7)

1. An automatic preassembling test platform for reactor production is characterized in that: the test platform comprises a test platform mechanism (1), wherein a processing mechanism (2) is arranged on the test platform mechanism (1);

The processing mechanism (2) comprises a rectangular hole (201), two round pipes (205), a water storage tank (206), two air guide holes (209), a storage tank (211) and a sealing plate (224), wherein a movable plate (202) is arranged in the rectangular hole (201), two symmetrical connecting frames (203) are arranged at the bottom of the movable plate (202), electric push rods (204) are arranged in the round pipes (205), air inlet pipes (208) are fixedly sleeved at the inner parts of the air guide holes (209) close to input ends, air suction pipes (207) are arranged at the inner parts of the air inlet pipes (208), air outlet pipes (210) are fixedly sleeved at the inner parts close to output ends of the air guide holes (209), a fan (213) is arranged at the upper inner side of the storage tank (211), a shell (214) is arranged at the bottom of the inner wall of the storage tank (211), a porous placing table (215) is arranged at the inner parts close to the bottom of the shell (214), an air suction pipe (207) is arranged at the input ends of the air inlet pipes (208), an air outlet pipe (210) is fixedly sleeved at the inner parts close to the output ends of the air outlet pipes (210), a three-way pipe (212) is arranged between the output ends of the air outlet pipes (210), a shell (214) is arranged at the top part of the air outlet pipe (216), the output end of the shell cover (218) is provided with a first air pipe (219), the bottom of the inner wall of the storage groove (211) is provided with a liquid storage box (220), a proper amount of sodium hydroxide solution is injected into the liquid storage box (220), one side of the inner wall of the liquid storage box (220) is fixedly penetrated with an L-shaped pipe (221), the input end of the L-shaped pipe (221) is provided with a one-way valve (222), and the output end of the fan (213) is provided with a second air pipe (223);

The bottoms of the telescopic ends of the two electric push rods (204) are respectively installed on the upper sides of the two connecting frames (203) through first screws, the input end of the fan (213) is connected with the output end of the three-way pipe (212), the drying layer (216) and the adsorption layer (217) are both positioned inside the shell (214), the input end of the L-shaped pipe (221) is close to the bottom of the inner wall of the shell (214), the input end of the one-way valve (222) is connected with the output end of the first air pipe (219), the output end of the second air pipe (223) is connected with the air inlet end of the shell (214), the outlet of the rectangular hole (201) is communicated with the top of the inner wall of the water storage tank (206), and the top of the air suction pipe (207) is fixed with the top of the inner wall of the water storage tank (206).

The testing platform mechanism (1) comprises a workbench (101) and a bottom plate (115), the rectangular hole (201) is formed in the top of the workbench (101), the water storage tank (206) is formed in the front surface of the workbench (101), the storage tank (211) is formed in the front surface of the workbench (101), the bottoms of the two round tubes (205) are fixed on the top of the workbench (101), the telescopic ends of the two electric push rods (204) are movably penetrated through the top of the workbench (101), and the telescopic ends of the two electric push rods (204) extend to the inside of the water storage tank (206);

Two air vent (209) are all offered between inner wall one side of aqua storage tank (206) and inner wall one side of storing groove (211), closing plate (224) are installed on the front surface of workstation (101) through the bolt, the top of workstation (101) is fixed with L shape piece (102), first hole (103) of placing has been seted up on the front surface of workstation (101), the inside of first hole (103) of placing is fixed with rectangle grid (104), the top of rectangle grid (104) sets up battery (105), second hole (106) of placing has been seted up near the rear side position to the front surface of L shape piece (102).

2. The automated preassembled test platform for reactor production of claim 1, wherein: the electric valve (225) is penetrated through the threads on the top of the inner wall of the storage groove (211), the input end of the electric valve (225) is communicated with the bottom of the inner wall of the water storage groove (206), and the top of the input end of the electric valve (225) and the bottom of the inner wall of the water storage groove (206) are positioned on the same horizontal plane.

3. The automated preassembled test platform for reactor production of claim 2, wherein: the inside of hole (106) is placed to the second is provided with display screen (107), the inside of hole (106) is placed to the second is close to the entrance and is installed fixed frame (108), the positive surface of display screen (107) contacts with the surface of fixed frame (108), rectangular channel (109) have been seted up to the upside of L shape piece (102), internally mounted in rectangular channel (109) has controller (110), winding displacement hole (111) have been seted up between the inner wall in rectangular channel (109) and the inner wall bottom in hole (106) is placed to the second.

4. An automated preassembly test platform for reactor production according to claim 3, wherein: the top of workstation (101) is fixed with places box (112), the open-top department of placing box (112) is provided with lid (113), crocodile clamp wire (114) are all installed to two ports of controller (110), and the centre gripping end of two crocodile clamp wires (114) all is in the inside of placing box (112), bottom plate (115) are installed at the top of movable plate (202) through the second screw, the top of workstation (101) is fixed with single hole piece (116).

5. The automated preassembled test platform for reactor production of claim 4, wherein: the inside of single hole piece (116) is equipped with infrared temperature sensor (117), battery (105) and controller (110) electric connection, display screen (107) and controller (110) electric connection, infrared temperature sensor (117) and controller (110) electric connection, two electric putter (204) all are with controller (110) electric connection, fan (213) and controller (110) electric connection, motorised valve (225) and controller (110) electric connection, the top of bottom plate (115) is fixed with two symmetrical hollow blocks (118).

6. The automated preassembled test platform for reactor production of claim 5, wherein: two the inside of hollow piece (118) all is provided with L shape pole (119), two the top of bottom plate (115) all is fixed with stopper (120), and two L shape poles (119) respectively with two stopper (120) recess looks adaptations, two the relative one end of L shape pole (119) all is connected with rectangular plate (121) through the bearing rotation, and the bottom of two rectangular plates (121) all contacts with the top of bottom plate (115), two the relative one side of rectangular plate (121) all bonds and is connected with cushion (122).

7. The automated preassembled test platform for reactor production of claim 6, wherein: the inner wall of hole (103) is close to the import department and rotates through the hinge and be connected with apron (123), and the positive surface of apron (123) is close to one side position and is locked in first inner wall one side of placing hole (103) through manual lock, first cylinder hole (124) have been seted up between inner wall one side of storing groove (211) and the inner wall of hole (103) are placed to first, the inside of first cylinder hole (124) is provided with sealing ring (125), second cylinder hole (126) have been seted up at the inner wall top of hole (103) are placed to first, the opening part of second cylinder hole (126) is linked together with the opening part of winding displacement hole (111).