Platform system for generating phosgene
阅读说明:本技术 一种用于生成光气平台系统 (Platform system for generating phosgene ) 是由 杨振宁 杜祥伦 秦令 张明 杨红 于 2021-08-31 设计创作,主要内容包括:本发明提出了一种用于生成光气平台系统,包括两个缓冲罐、两个Cl-(2)-CO混合器、两个COCl-(2)生成反应器、COCl-(2)反应保护器、COCl-(2)分配器、五个流量电磁阀、五个通断电磁阀和M个分配电磁阀;两个缓冲罐分别为Cl-(2)缓冲罐和CO缓冲罐,两个Cl-(2)-CO混合器分别为Cl-(2)-CO第一混合器和Cl-(2)-CO第二混合器,两个COCl-(2)生成反应器分别为COCl-(2)第一生成反应器和COCl-(2)第二生成反应器;五个流量电磁阀分别为第一流量电磁阀、第二流量电磁阀、第三流量电磁阀、第四流量电磁阀和第五流量电磁阀,五个通断电磁阀分别为第一通断电磁阀、第二通断电磁阀、第三通断电磁阀、第四通断电磁阀和第五通断电磁阀。本发明能够对COCl-(2)进行安全性生产,实现平台化控制。(The invention provides a platform system for generating phosgene, which comprises two buffer tanks and two Cl 2 -CO mixer, two COCl 2 Generation reactor, COCl 2 Reaction protector, COCl 2 The system comprises a distributor, five flow electromagnetic valves, five on-off electromagnetic valves and M distribution electromagnetic valves; two buffer tanks are respectively Cl 2 Buffer tank and CO buffer tank, two Cl 2 respectively-CO mixers are Cl 2 -first mixer of CO and Cl 2 -second CO mixer, two COCl 2 The generation reactors are respectively COCl 2 First generation reactor and COCl 2 A second generation reactor; the five flow electromagnetic valves are respectively a first flow electromagnetic valve, a second flow electromagnetic valve, a third flow electromagnetic valve, a fourth flow electromagnetic valve and a fifth flow electromagnetic valve, and the five on-off electromagnetic valves are dividedA first on-off solenoid valve, a second on-off solenoid valve, a third on-off solenoid valve, a fourth on-off solenoid valve and a fifth on-off solenoid valve. The invention can be used for the COCl 2 And carrying out safety production and realizing platform control.)
1. A platform system for generating phosgene is characterized by comprising two platformsA buffer tank and two Cl2-CO mixer, two COCl2Production reactor, COCl2Reaction protector, COCl2The system comprises a distributor, five flow electromagnetic valves, five on-off electromagnetic valves and M distribution electromagnetic valves; m is a positive integer greater than or equal to 1;
two buffer tanks are respectively Cl2Buffer tank and CO buffer tank, two Cl2respectively-CO mixers are Cl2-first mixer of CO and Cl2Second mixer of CO, two COCl2The generation reactors are respectively COCl2First generation reactor and COCl2A second generation reactor; the five flow solenoid valves are respectively a first flow solenoid valve, a second flow solenoid valve, a third flow solenoid valve, a fourth flow solenoid valve and a fifth flow solenoid valve, and the five on-off solenoid valves are respectively a first on-off solenoid valve, a second on-off solenoid valve, a third on-off solenoid valve, a fourth on-off solenoid valve and a fifth on-off solenoid valve; the M distribution electromagnetic valves are respectively a first distribution electromagnetic valve, a second distribution electromagnetic valve, a third distribution electromagnetic valve, … … and an Mth distribution electromagnetic valve;
Cl2cl of buffer tank2The inlet end of the pipeline is connected with the outlet end of the first flow electromagnetic valve, Cl2Cl of buffer tank2The outlet end of the pipeline is connected with the inlet end of a second flow electromagnetic valve, and the outlet end of the second flow electromagnetic valve is connected with Cl2-Cl of the CO first mixer2The inlet end of a CO pipeline of the CO buffer tank is connected with the inlet end of a third flow electromagnetic valve, the outlet end of the CO pipeline of the CO buffer tank is connected with the inlet end of a fourth flow electromagnetic valve, and the outlet end of the fourth flow electromagnetic valve is connected with Cl2-the CO inlet end of the first CO mixer is connected; cl2The mixing outlet of the first CO mixer is connected to the inlet of a first on-off solenoid valve, the outlet of which is connected to the COCl2The reaction inlet end of the first generation reactor is connected with the COCl2The reaction outlet end of the first generation reactor is connected with the reactant inlet end of the second electromagnetic opening valve, and the reactant outlet end of the second electromagnetic opening valve is connected with Cl2-the mixing inlet ends of the CO second mixers are connected;
Cl2cl of buffer tank2The outlet end of the pipeline is also connected with the inlet end of a fifth flow electromagnetic valve, and the outlet end of the fifth flow electromagnetic valve is connected with Cl2-Cl of the second CO mixer2Inlet end connected, Cl2The mixing outlet end of the-CO second mixer is connected with the inlet end of a third cut-off solenoid valve, and the outlet end of the third cut-off solenoid valve is connected with the COCl2The reaction inlet end of the second generation reactor is connected with the COCl2The reaction outlet end of the second generation reactor is connected with the inlet end of a fourth electromagnetic valve, and the outlet end of the fourth electromagnetic valve is connected with the COCl2Inlet end connection of reaction protector, COCl2The outlet end of the reaction protector is connected with the inlet end of a fifth on-off solenoid valve, and the outlet end of the fifth on-off solenoid valve is connected with the COCl2COCl of distributor2The inlet ends are connected;
COCl2first COCl of distributor2COCl of distribution end and first distribution solenoid valve2Inlet end connected, COCl2Second COCl of distributor2COCl of distribution end and second distribution electromagnetic valve2Inlet end connected, COCl2Third COCl of distributor2COCl of distribution end and third distribution solenoid valve2Inlet end connection, … …, COCl2Mth COCl of distributor2COCl of distribution end and Mth distribution solenoid valve2The inlet ends are connected;
the first flow control end of the controller is connected with the flow control end of the first flow electromagnetic valve, the second flow control end of the controller is connected with the flow control end of the second flow electromagnetic valve, the third flow control end of the controller is connected with the flow control end of the third flow electromagnetic valve, the fourth flow control end of the controller is connected with the flow control end of the fourth flow electromagnetic valve, and the fifth flow control end of the controller is connected with the flow control end of the fifth flow electromagnetic valve; a first on-off control end of the controller is connected with a flow control end of the first on-off electromagnetic valve, a second on-off control end of the controller is connected with a flow control end of the second on-off electromagnetic valve, a third on-off control end of the controller is connected with a flow control end of the third on-off electromagnetic valve, a fourth on-off control end of the controller is connected with a flow control end of the fourth on-off electromagnetic valve, and a fifth on-off control end of the controller is connected with a flow control end of the fifth on-off electromagnetic valve; a first distribution control end of the controller is connected with a flow control end of a first distribution electromagnetic valve, a second distribution control end of the controller is connected with a flow control end of a second distribution electromagnetic valve, a third distribution control end of the controller is connected with a flow control end of a third distribution electromagnetic valve, … …, and an Mth distribution control end of the controller is connected with a flow control end of an Mth distribution electromagnetic valve;
and the controller receives a control command sent by the cloud platform according to the data transmission module and generates the COCl2By COCl2The dispenser dispenses.
2. The system for generating phosgene platform of claim 1, further comprising sending control commands to its controller by logging onto a cloud platform with a mobile intelligent handheld terminal.
3. The system for generating phosgene platform of claim 1, wherein the data transmission module comprises a data transmission wireless module or/and a data transmission wired module;
the wireless data transmission end of the data transmission wireless module is connected with the wireless data transmission end of the controller, and the wired data transmission end of the data transmission wired module is connected with the wired data transmission end of the controller.
4. The system for generating phosgene platform of claim 3, wherein the data transmission wireless module comprises one or any combination of a WiFi data transmission wireless module, a 4G data transmission wireless module, a 5G data transmission wireless module, and a Lora data transmission wireless module;
the wireless data transmission end of the WiFi data transmission wireless module is connected with the WiFi wireless data transmission end of the controller, the wireless data transmission end of the 4G data transmission wireless module is connected with the 4G wireless data transmission end of the controller, the wireless data transmission end of the 5G data transmission wireless module is connected with the 5G wireless data transmission end of the controller, and the wireless data transmission end of the Lora data transmission wireless module is connected with the Lora wireless data transmission end of the controller.
5. The system of claim 3, wherein the wired data transmission modules comprise one or any combination of RS485 wired data transmission modules, hundred mega RJ45 wired data transmission modules, gigabit RJ45 wired data transmission modules;
the wired data transmission end of the RS485 data transmission wired module is connected with the RS485 wired data transmission end of the controller, the wired data transmission end of the hundred-million RJ45 data transmission wired module is connected with the hundred-million RJ45 wired data transmission end of the controller, and the wired data transmission end of the kilomega RJ45 data transmission wired module is connected with the kilomega RJ45 wired data transmission end of the controller.
6. The platform system for generating phosgene of claim 1, further comprising Cl2The preheating tank, the CO preheating tank, the sixth on-off electromagnetic valve and the seventh on-off electromagnetic valve;
inlet end and Cl of sixth switching electromagnetic valve2Cl of buffer tank2The outlet end of the pipeline is connected, and the outlet end of the sixth switching-off electromagnetic valve is connected with Cl2Preheating inlet end of preheating tank, Cl2The preheating outlet end of the preheating tank is connected with the inlet end of the second flow electromagnetic valve; cl2The preheating outlet end of the preheating tank is also connected with the inlet end of a fifth flow electromagnetic valve; the inlet end of the seventh on-off electromagnetic valve is connected with the outlet end of the CO pipeline of the CO buffer tank, the outlet end of the seventh on-off electromagnetic valve is connected with the preheating inlet end of the CO preheating tank, and the preheating outlet end of the CO preheating tank is connected with the inlet end of the fourth flow electromagnetic valve.
7. The system of claim 1, further comprising a water circulator, a first outlet of the water circulator and the COCl2The cooling inlet end of the first generation reactor is connected with the water circulationThe first inlet end of the device is connected with the inlet end of an eighth on-off solenoid valve, and the outlet end of the eighth on-off solenoid valve is connected with the COCl2The cooling outlet end of the first generation reactor is connected; in COCl2A first temperature sensor is arranged in the first generation reactor, and the temperature data output end of the first temperature sensor is connected with the temperature data input end of the controller; the flow control end of the eighth on-off electromagnetic valve is connected with the eighth on-off control end of the controller;
second outlet end of water circulator and COCl2The cooling inlet end of the second generation reactor is connected, the second inlet end of the water circulator is connected with the inlet end of a ninth on-off solenoid valve, and the outlet end of the ninth on-off solenoid valve is connected with the COCl2The cooling outlet end of the second generation reactor is connected; in COCl2A second temperature sensor is arranged in the second generation reactor, and the temperature data output end of the second temperature sensor is connected with the temperature data input end of the controller; and the flow control end of the ninth on-off electromagnetic valve is connected with the ninth on-off control end of the controller.
8. The platform system for generating phosgene of claim 6, wherein a first pressure sensor and/or a third temperature sensor is/are disposed in the CO preheating tank, a pressure data output terminal of the first pressure sensor is connected to a first pressure data input terminal of the controller, a temperature data output terminal of the third temperature sensor is connected to a third temperature data input terminal of the controller, a warming inlet terminal of the CO preheating tank is connected to a third outlet terminal of the water circulator, a warming outlet terminal of the CO preheating tank is connected to an inlet terminal of a tenth on-off solenoid valve, an outlet terminal of the tenth on-off solenoid valve is connected to a third inlet terminal of the water circulator, and a flow control terminal of the tenth on-off solenoid valve is connected to a tenth on-off control terminal of the controller;
in Cl2A second pressure sensor or/and a fourth temperature sensor are/is arranged in the preheating tank, the pressure data output end of the second pressure sensor is connected with the second pressure data input end of the controller, the temperature data output end of the fourth temperature sensor is connected with the fourth temperature data input end of the controller, and Cl is added2PreheatingThe warming inlet end of the tank is connected to the fourth outlet end of the water circulator, Cl2The heating outlet end of the preheating tank is connected with the inlet end of an eleventh on-off electromagnetic valve, the outlet end of the eleventh on-off electromagnetic valve is connected with the fourth inlet end of the water circulator, and the flow control end of the eleventh on-off electromagnetic valve is connected with the eleventh on-off control end of the controller.
9. The system for generating phosgene platform according to one of claims 1 to 8, characterized by the following steps:
s3a, initializing the system, the initialization including:
the controller respectively sends closing control signals to the first flow electromagnetic valve to the fifth flow electromagnetic valve, sends closing control signals to the first on-off electromagnetic valve to the eleventh on-off electromagnetic valve and sends closing control signals to the first distribution electromagnetic valve to the Mth distribution electromagnetic valve; the pipeline is in a cut-off state;
s3b, if the controller receives the generated COCl2Triggering the control signal, the controller respectively sends out opening control signals to the first flow electromagnetic valve and the third flow electromagnetic valve, and the control signal is controlled to enter Cl2Cl in buffer tank2The amount of CO and the amount of CO entering the CO surge tank;
when the first flow solenoid valve and/or the third flow solenoid valve T are opened1After min, the T1The controller respectively sends opening control commands to a tenth on-off solenoid valve and an eleventh on-off solenoid valve to enable circulating water in the water circulator to circulate Cl pairs2Preheating the preheating tank and the CO preheating tank;
s3c, when it entered Cl2Cl in buffer tank2In an amount equal to the predetermined Cl2At threshold, the controller sends a close signal to its first flow solenoid valve, no longer to Cl2Conveying Cl in buffer tank2(ii) a When the amount of CO entering the CO buffer tank is equal to the preset CO threshold value, the controller sends a closing signal to the third flow electromagnetic valve of the controller, and CO is not conveyed into the CO buffer tank any more;
s3d, when the controller receives the fourth temperatureThe temperature value collected by the temperature sensor is equal to the preset Cl2When the temperature is higher than the threshold value, the controller sends an opening control signal to a sixth on-off electromagnetic valve to enable the sixth on-off electromagnetic valve to be Cl2Cl in buffer tank2Into Cl2Preheating in a preheating tank; when the controller receives that the temperature value acquired by the fourth temperature sensor is equal to the preset Cl2Preheating temperature threshold, Cl2The preheating temperature threshold is larger than the preset Cl2When the temperature is in the threshold value, the controller sends an opening control signal to the second flow electromagnetic valve to ensure that the preheated Cl is heated2Into Cl2CO first mixer and as it enters Cl2-Cl of the CO first mixer2In an amount equal to the predetermined Cl2The mixing threshold, then the controller sends a closing control signal to its second flow solenoid valve, no longer to Cl2-conveying Cl in a CO first mixer2;
When the controller receives that the temperature value acquired by the third temperature sensor is equal to the preset CO temperature threshold value, the controller sends an opening control signal to a seventh on-off electromagnetic valve of the controller, so that CO in a CO buffer tank enters a CO preheating tank for preheating; when the temperature value acquired by the third temperature sensor and received by the controller is equal to the preset CO preheating temperature threshold value which is greater than the preset CO temperature threshold value, the controller sends an opening control signal to a fourth flow electromagnetic valve of the controller, so that the preheated CO enters Cl2CO first mixer and as it enters Cl2-the CO quantity of the first CO mixer is equal to the preset CO mixing threshold, the controller sends a closing control signal to its fourth flow solenoid valve, no longer to Cl2-transporting CO in a CO first mixer;
s3e, to Cl2And CO in Cl2After sufficient mixing in the first CO mixer, the controller sends an opening control signal to the first on-off solenoid valve to release Cl2-Cl in the first CO mixer2With CO into COCl2The first generation reactor carries out reaction; to be Cl2-Cl in the first CO mixer2The mixed gas with CO is discharged into COCl2After the first generation reactor, the controller sends a closing control signal to a first on-off electromagnetic valve of the first generation reactor to enable the first on-off electromagnetic valve to be Cl2First mixer of CO to COCl2Introducing Cl into the first generation reactor2Closing a pipeline of the mixed gas with CO;
s3f, when the controller receives that the temperature value acquired by the first temperature sensor is greater than or equal to a preset first temperature threshold value, the controller sends an opening control signal to an eighth on-off solenoid valve of the controller to enable circulating water in a water circulator of the controller to circulate to COCl2Cooling the first generation reactor; when reaction T is carried out2After min time, said T2Is greater than T1The controller sends an opening control signal to the second electromagnetic opening valve to enable the COCl of the controller to be in a COCl state2Introducing Cl into the residual gas which is not reacted in the first generation reactor2In a second CO mixer, to be COCl2All the unreacted residual gas in the first generation reactor is introduced with Cl2After the second mixer of CO, the controller sends a closing control signal to its second on-off solenoid valve, causing its COCl2First generation reactor to Cl2The pipeline for feeding the unreacted residual gas into the CO second mixer is closed;
s3g, the controller sends an opening control signal to the fifth flow electromagnetic valve to ensure that the preheated Cl is ensured2Into Cl2-CO second mixer and as it enters Cl2-Cl of the second CO mixer2In an amount equal to the predetermined Cl2The second mixing threshold value, the controller sends a closing control signal to the fifth flow electromagnetic valve of the controller, and the second mixing threshold value is not sent to Cl2-CO second Mixer for Cl2(ii) a To be Cl2-after the gas in the second CO mixer is sufficiently mixed, the controller sends an opening control signal to the third electromagnetic valve to open the third electromagnetic valve, so as to enable Cl2The mixed gas in the second CO mixer is discharged into the COCl2The second generation reactor carries out reaction; to be Cl2The mixed gas in the second CO mixer is discharged into the COCl2After the second generation reactor, the controller sends a closing control signal to a third cut-off solenoid valve of the second generation reactor to enable the third cut-off solenoid valve to be Cl2Second mixer of CO to COCl2Closing a pipeline for introducing mixed gas into the second generation reactor;
s3h, when the controller receives that the temperature value collected by the second temperature sensor is greater than or equal to the preset second temperatureWhen the temperature is above the threshold value, the controller sends an opening control signal to the ninth on-off electromagnetic valve to enable circulating water in the water circulator to circulate the COCl2Cooling the second generation reactor; when reaction T is carried out3After min time, said T3Is greater than T1Is a positive number of, and T3Is less than T2The controller sends an opening control signal to the fourth electromagnetic valve to enable the COCl of the controller to be opened2Introducing COCl into the substances in the second generation reactor2In a reaction protector, to be COCl2The COCl is introduced into all the substances in the second generation reactor2After the protector is reacted, the controller sends a closing control signal to the fourth electromagnetic valve to enable the COCl of the fourth electromagnetic valve to be closed2Second generation reactor to COCl2Closing a pipeline for introducing substances into the reaction protector;
s3i, the controller sends out opening control signal to the fifth on-off solenoid valve to make it COCl2Introduction of COCl2Distributor to treat COCl2All being passed through COCl2After the distributor, the controller sends a closing control signal to the fifth on-off solenoid valve to enable the controller to control the COCl2Reaction protector towards COCl2The distributor is filled with COCl2The pipe (2) is closed.
10. The system for generating phosgene platform of claim 2, wherein the means for logging in with a mobile intelligent handheld terminal comprises the steps of:
s11, the login client judges whether the login client remembers the login account and the login password to log in:
if the login mode is to remember the login account and the login password, executing step S12;
if the login mode is not to remember the login account and the login password, executing step S16;
s12, acquiring the unique ID code and the login symbol of the mobile intelligent handheld terminal, wherein the unique ID code of the mobile intelligent handheld terminal comprises one of a CPU unique ID number, a mainboard unique ID number and an RAM unique ID number; calculating the obtained unique ID code and login symbol of the mobile intelligent handheld terminal to obtain a login check code of the mobile intelligent handheld terminal;
judging whether the login check code obtained by calculation is consistent with the login check code stored on the login client side:
if the calculated login check code is consistent with the login check code stored in the login client, executing step S13;
if the calculated login check code is not consistent with the login check code stored on the login client, executing S16;
s13, acquiring the saved safe login account and the safe login password, and analyzing the acquired safe login account and the safe login password to obtain the login account and the login password;
s14, carrying out safe transmission processing on the obtained login account and login password to obtain a transmission login account and a transmission login password thereof;
s15, sending the obtained transmission login account and the obtained transmission login password to the cloud platform for verification;
s16, the login account inputted by the account input box and the login password inputted by the password input box are extracted, and the step S14 is executed.
Technical Field
The invention relates to the technical field of chemical engineering, in particular to a platform system for generating phosgene.
Background
Phosgene (COCl)2) Also called phosgene, is extremely toxic, slightly soluble in water, and easily soluble in benzene, toluene and the like. Is prepared from the mixture of CO and Cl through activated carbon. Phosgene is colorless gas at normal temperature, has rotten grass smell and unstable chemical property, and is rapidly hydrolyzed when meeting water to generate hydrogen chloride. Is one of the high-temperature pyrolysis products of the chlorine plastic. It is used as intermediate for organic synthesis, pesticide, medicine, dye and other chemical products. Phosgene is produced when aliphatic chlorocarbons (e.g., chloroform, trichloroethylene, etc.) are combusted. The phosgene in the environment mainly comes from the production processes of dyes, pesticides, pharmacy and the like. Phosgene is a severe asphyxia poison gas, which can cause pulmonary edema when inhaled at high concentration. It is about 10 times more toxic than chlorine gas, but has no accumulation in body. Patent application No. 201320668265X, entitled "a safe phosgene preparation device," includes a first constant flow pump, a second constant flow pump, a third constant flow pump, a micro mixer, a first microchannel reactor, a second microchannel reactor, a product receiver, and a thermostatic bath; the second constant flow pump and the third constant flow pump are connected with a micro mixer, the micro mixer is connected with a first micro-channel reactor, the first micro-channel reactor is connected with a second micro-channel reactor, and the second micro-channel reactor is connected with a product receiver; the first constant flow pump is arranged between the first microchannel reactor and the second microchannel reactor; the micro mixer and the micro channel reactor are both arranged in a constant temperature bath.
Disclosure of Invention
The invention aims to at least solve the technical problems in the prior art, and particularly provides a platform system for generating phosgene.
In order to achieve the above object, the present invention provides a platform system for generating phosgene, comprising two buffer tanks, two Cl2-CO mixer, two COCl2Generation reactor, COCl2Reaction protector, COCl2The system comprises a distributor, five flow electromagnetic valves, five on-off electromagnetic valves and M distribution electromagnetic valves; m is a positive integer greater than or equal to 1;
two buffer tanks are respectively Cl2Buffer tank and CO buffer tank, two Cl2respectively-CO mixers are Cl2-first mixer of CO and Cl2Second mixer of CO, two COCl2The generation reactors are respectively COCl2First generation reactor and COCl2A second generation reactor; the five flow solenoid valves are respectively a first flow solenoid valve, a second flow solenoid valve, a third flow solenoid valve, a fourth flow solenoid valve and a fifth flow solenoid valve, and the five on-off solenoid valves are respectively a first on-off solenoid valve, a second on-off solenoid valve, a third on-off solenoid valve, a fourth on-off solenoid valve and a fifth on-off solenoid valve; the M distribution electromagnetic valves are respectively a first distribution electromagnetic valve, a second distribution electromagnetic valve, a third distribution electromagnetic valve, … … and an Mth distribution electromagnetic valve;
Cl2cl of buffer tank2The inlet end of the pipeline is connected with the outlet end of the first flow electromagnetic valve, Cl2Cl of buffer tank2The outlet end of the pipeline is connected with the inlet end of a second flow electromagnetic valve, and the outlet end of the second flow electromagnetic valve is connected with Cl2-Cl of the CO first mixer2The inlet end of a CO pipeline of the CO buffer tank is connected with the inlet end of a third flow electromagnetic valve, the outlet end of the CO pipeline of the CO buffer tank is connected with the inlet end of a fourth flow electromagnetic valve, and the outlet end of the fourth flow electromagnetic valve is connected with Cl2-the CO inlet end of the first CO mixer is connected; cl2The mixing outlet of the first CO mixer is connected to the inlet of a first on-off solenoid valve, the outlet of which is connected to the COCl2The reaction inlet end of the first generation reactor is connected with the COCl2The reaction outlet end of the first generation reactor is connected with the reactant inlet end of the second electromagnetic opening valve, and the reactant outlet end of the second electromagnetic opening valve is connected with Cl2-the mixing inlet ends of the CO second mixers are connected;
Cl2cl of buffer tank2The outlet end of the pipeline is also connected with the inlet end of a fifth flow electromagnetic valveOutlet end of magnetic valve and Cl2-Cl of the second CO mixer2Inlet end connected, Cl2The mixing outlet end of the-CO second mixer is connected with the inlet end of a third cut-off solenoid valve, and the outlet end of the third cut-off solenoid valve is connected with the COCl2The reaction inlet end of the second generation reactor is connected with the COCl2The reaction outlet end of the second generation reactor is connected with the inlet end of a fourth electromagnetic valve, and the outlet end of the fourth electromagnetic valve is connected with the COCl2Inlet end connection of reaction protector, COCl2The outlet end of the reaction protector is connected with the inlet end of a fifth on-off solenoid valve, and the outlet end of the fifth on-off solenoid valve is connected with the COCl2COCl of distributor2The inlet ends are connected;
COCl2first COCl of distributor2COCl of distribution end and first distribution solenoid valve2Inlet end connected, COCl2Second COCl of distributor2COCl of distribution end and second distribution electromagnetic valve2Inlet end connected, COCl2Third COCl of distributor2COCl of distribution end and third distribution solenoid valve2Inlet end connection, … …, COCl2Mth COCl of distributor2COCl of distribution end and Mth distribution solenoid valve2The inlet ends are connected;
the first flow control end of the controller is connected with the flow control end of the first flow electromagnetic valve, the second flow control end of the controller is connected with the flow control end of the second flow electromagnetic valve, the third flow control end of the controller is connected with the flow control end of the third flow electromagnetic valve, the fourth flow control end of the controller is connected with the flow control end of the fourth flow electromagnetic valve, and the fifth flow control end of the controller is connected with the flow control end of the fifth flow electromagnetic valve; a first on-off control end of the controller is connected with a flow control end of the first on-off electromagnetic valve, a second on-off control end of the controller is connected with a flow control end of the second on-off electromagnetic valve, a third on-off control end of the controller is connected with a flow control end of the third on-off electromagnetic valve, a fourth on-off control end of the controller is connected with a flow control end of the fourth on-off electromagnetic valve, and a fifth on-off control end of the controller is connected with a flow control end of the fifth on-off electromagnetic valve; a first distribution control end of the controller is connected with a flow control end of a first distribution electromagnetic valve, a second distribution control end of the controller is connected with a flow control end of a second distribution electromagnetic valve, a third distribution control end of the controller is connected with a flow control end of a third distribution electromagnetic valve, … …, and an Mth distribution control end of the controller is connected with a flow control end of an Mth distribution electromagnetic valve;
and the controller receives a control command sent by the cloud platform according to the data transmission module and generates the COCl2By COCl2The dispenser dispenses.
In a preferred embodiment of the invention, the method further comprises sending a control command to a controller of the mobile intelligent handheld terminal by logging in the cloud platform through the mobile intelligent handheld terminal.
In a preferred embodiment of the present invention, the data transmission module comprises a data transmission wireless module or/and a data transmission wired module;
the wireless data transmission end of the data transmission wireless module is connected with the wireless data transmission end of the controller, and the wired data transmission end of the data transmission wired module is connected with the wired data transmission end of the controller.
In a preferred embodiment of the present invention, the data transmission wireless module includes one or any combination of a WiFi data transmission wireless module, a 4G data transmission wireless module, a 5G data transmission wireless module, and a Lora data transmission wireless module;
the wireless data transmission end of the WiFi data transmission wireless module is connected with the WiFi wireless data transmission end of the controller, the wireless data transmission end of the 4G data transmission wireless module is connected with the 4G wireless data transmission end of the controller, the wireless data transmission end of the 5G data transmission wireless module is connected with the 5G wireless data transmission end of the controller, and the wireless data transmission end of the Lora data transmission wireless module is connected with the Lora wireless data transmission end of the controller.
In a preferred embodiment of the present invention, the data transmission wired module includes one or any combination of an RS485 data transmission wired module, a hundred mega RJ45 data transmission wired module, and a gigabit RJ45 data transmission wired module;
the wired data transmission end of the RS485 data transmission wired module is connected with the RS485 wired data transmission end of the controller, the wired data transmission end of the hundred-million RJ45 data transmission wired module is connected with the hundred-million RJ45 wired data transmission end of the controller, and the wired data transmission end of the kilomega RJ45 data transmission wired module is connected with the kilomega RJ45 wired data transmission end of the controller.
In a preferred embodiment of the present invention, further comprises Cl2The preheating tank, the CO preheating tank, the sixth on-off electromagnetic valve and the seventh on-off electromagnetic valve;
inlet end and Cl of sixth switching electromagnetic valve2Cl of buffer tank2The outlet end of the pipeline is connected, and the outlet end of the sixth switching-off electromagnetic valve is connected with Cl2Preheating inlet end of preheating tank, Cl2The preheating outlet end of the preheating tank is connected with the inlet end of the second flow electromagnetic valve; cl2The preheating outlet end of the preheating tank is also connected with the inlet end of a fifth flow electromagnetic valve; the inlet end of the seventh on-off electromagnetic valve is connected with the outlet end of the CO pipeline of the CO buffer tank, the outlet end of the seventh on-off electromagnetic valve is connected with the preheating inlet end of the CO preheating tank, and the preheating outlet end of the CO preheating tank is connected with the inlet end of the fourth flow electromagnetic valve.
In a preferred embodiment of the present invention, the apparatus further comprises a water circulator, wherein the first outlet end of the water circulator is connected with the COCl2The cooling inlet end of the first generation reactor is connected, the first inlet end of the water circulator is connected with the inlet end of an eighth on-off electromagnetic valve, and the outlet end of the eighth on-off electromagnetic valve is connected with the COCl2The cooling outlet end of the first generation reactor is connected; in COCl2A first temperature sensor is arranged in the first generation reactor, and the temperature data output end of the first temperature sensor is connected with the temperature data input end of the controller; the flow control end of the eighth on-off electromagnetic valve is connected with the eighth on-off control end of the controller;
second outlet end of water circulator and COCl2The cooling inlet end of the second generation reactor is connected, the second inlet end of the water circulator is connected with the inlet end of a ninth on-off electromagnetic valve, and a ninth channel is arrangedOutlet end of solenoid valve and COCl2The cooling outlet end of the second generation reactor is connected; in COCl2A second temperature sensor is arranged in the second generation reactor, and the temperature data output end of the second temperature sensor is connected with the temperature data input end of the controller; and the flow control end of the ninth on-off electromagnetic valve is connected with the ninth on-off control end of the controller.
In a preferred embodiment of the present invention, a first pressure sensor or/and a third temperature sensor are disposed in the CO preheating tank, a pressure data output end of the first pressure sensor is connected to a first pressure data input end of the controller, a temperature data output end of the third temperature sensor is connected to a third temperature data input end of the controller, a warming inlet end of the CO preheating tank is connected to a third outlet end of the water circulator, a warming outlet end of the CO preheating tank is connected to an inlet end of a tenth on-off solenoid valve, an outlet end of the tenth on-off solenoid valve is connected to a third inlet end of the water circulator, and a flow control end of the tenth on-off solenoid valve is connected to a tenth on-off control end of the controller;
in Cl2A second pressure sensor or/and a fourth temperature sensor are/is arranged in the preheating tank, the pressure data output end of the second pressure sensor is connected with the second pressure data input end of the controller, the temperature data output end of the fourth temperature sensor is connected with the fourth temperature data input end of the controller, and Cl is added2The heating inlet end of the preheating tank is connected with the fourth outlet end of the water circulator, and Cl2The heating outlet end of the preheating tank is connected with the inlet end of an eleventh on-off electromagnetic valve, the outlet end of the eleventh on-off electromagnetic valve is connected with the fourth inlet end of the water circulator, and the flow control end of the eleventh on-off electromagnetic valve is connected with the eleventh on-off control end of the controller.
In a preferred embodiment of the invention, the method comprises the following steps:
s1, logging in a cloud platform by using the mobile intelligent handheld terminal;
s2, after logging in the cloud platform, changing the control parameters, and sending the changed control parameters to the controller;
and S3, after the controller verifies, taking the changed control parameters as the control parameters of the current operation and the subsequent operation.
In a preferred embodiment of the present invention, in step S3, the method for operating when the controller does not receive the control parameter modification includes the following steps:
s3a, initializing the system, the initialization including:
the controller respectively sends closing control signals to the first flow electromagnetic valve to the fifth flow electromagnetic valve, sends closing control signals to the first on-off electromagnetic valve to the eleventh on-off electromagnetic valve and sends closing control signals to the first distribution electromagnetic valve to the Mth distribution electromagnetic valve; the pipeline is in a cut-off state;
s3b, if the controller receives the generated COCl2Triggering the control signal, the controller respectively sends out opening control signals to the first flow electromagnetic valve and the third flow electromagnetic valve, and the control signal is controlled to enter Cl2Cl in buffer tank2The amount of CO and the amount of CO entering the CO surge tank;
when the first flow solenoid valve and/or the third flow solenoid valve T are opened1After min, the T1The controller respectively sends opening control commands to a tenth on-off solenoid valve and an eleventh on-off solenoid valve to enable circulating water in the water circulator to circulate Cl pairs2Preheating the preheating tank and the CO preheating tank;
s3c, when it entered Cl2Cl in buffer tank2In an amount equal to the predetermined Cl2At threshold, the controller sends a close signal to its first flow solenoid valve, no longer to Cl2Conveying Cl in buffer tank2(ii) a When the amount of CO entering the CO buffer tank is equal to the preset CO threshold value, the controller sends a closing signal to the third flow electromagnetic valve of the controller, and CO is not conveyed into the CO buffer tank any more;
s3d, when the controller receives that the temperature value collected by the fourth temperature sensor is equal to the preset Cl2When the temperature is higher than the threshold value, the controller sends an opening control signal to a sixth on-off electromagnetic valve to enable the sixth on-off electromagnetic valve to be Cl2Cl in buffer tank2Into Cl2Preheating in a preheating tank; when the controller receives the fourth temperature signalThe temperature value collected by the sensor is equal to the preset Cl2Preheating temperature threshold, Cl2The preheating temperature threshold is larger than the preset Cl2When the temperature is in the threshold value, the controller sends an opening control signal to the second flow electromagnetic valve to ensure that the preheated Cl is heated2Into Cl2CO first mixer and as it enters Cl2-Cl of the CO first mixer2In an amount equal to the predetermined Cl2The mixing threshold, then the controller sends a closing control signal to its second flow solenoid valve, no longer to Cl2-conveying Cl in a CO first mixer2;
When the controller receives that the temperature value acquired by the third temperature sensor is equal to the preset CO temperature threshold value, the controller sends an opening control signal to a seventh on-off electromagnetic valve of the controller, so that CO in a CO buffer tank enters a CO preheating tank for preheating; when the temperature value acquired by the third temperature sensor and received by the controller is equal to the preset CO preheating temperature threshold value which is greater than the preset CO temperature threshold value, the controller sends an opening control signal to a fourth flow electromagnetic valve of the controller, so that the preheated CO enters Cl2CO first mixer and as it enters Cl2-the CO quantity of the first CO mixer is equal to the preset CO mixing threshold, the controller sends a closing control signal to its fourth flow solenoid valve, no longer to Cl2-transporting CO in a CO first mixer;
s3e, to Cl2And CO in Cl2After sufficient mixing in the first CO mixer, the controller sends an opening control signal to the first on-off solenoid valve to release Cl2-Cl in the first CO mixer2With CO into COCl2The first generation reactor carries out reaction; to be Cl2-Cl in the first CO mixer2The mixed gas with CO is discharged into COCl2After the first generation reactor, the controller sends a closing control signal to a first on-off electromagnetic valve of the first generation reactor to enable the first on-off electromagnetic valve to be Cl2First mixer of CO to COCl2Introducing Cl into the first generation reactor2Closing a pipeline of the mixed gas with CO;
s3f, when the controller receives that the temperature value collected by the first temperature sensor is greater than or equal to the preset first temperature threshold value, the controller sends the eighth temperature threshold value to the controllerThe on-off solenoid valve sends out an opening control signal to enable circulating water in the water circulator to circulate to COCl2Cooling the first generation reactor; when reaction T is carried out2After min time, said T2Is greater than T1The controller sends an opening control signal to the second electromagnetic opening valve to enable the COCl of the controller to be in a COCl state2Introducing Cl into the residual gas which is not reacted in the first generation reactor2In a second CO mixer, to be COCl2All the unreacted residual gas in the first generation reactor is introduced with Cl2After the second mixer of CO, the controller sends a closing control signal to its second on-off solenoid valve, causing its COCl2First generation reactor to Cl2The pipeline for feeding the unreacted residual gas into the CO second mixer is closed;
s3g, the controller sends an opening control signal to the fifth flow electromagnetic valve to ensure that the preheated Cl is ensured2Into Cl2-CO second mixer and as it enters Cl2-Cl of the second CO mixer2In an amount equal to the predetermined Cl2The second mixing threshold value, the controller sends a closing control signal to the fifth flow electromagnetic valve of the controller, and the second mixing threshold value is not sent to Cl2-CO second Mixer for Cl2(ii) a To be Cl2-after the gas in the second CO mixer is sufficiently mixed, the controller sends an opening control signal to the third electromagnetic valve to open the third electromagnetic valve, so as to enable Cl2The mixed gas in the second CO mixer is discharged into the COCl2The second generation reactor carries out reaction; to be Cl2The mixed gas in the second CO mixer is discharged into the COCl2After the second generation reactor, the controller sends a closing control signal to a third cut-off solenoid valve of the second generation reactor to enable the third cut-off solenoid valve to be Cl2Second mixer of CO to COCl2Closing a pipeline for introducing mixed gas into the second generation reactor;
s3h, when the controller receives that the temperature value acquired by the second temperature sensor is greater than or equal to a preset first temperature threshold value, the controller sends an opening control signal to a ninth on-off solenoid valve of the controller to enable circulating water in the water circulator to circulate to COCl2Cooling the second generation reactor; when reaction T is carried out3After min time, said T3Is greater than T1Is a positive number of, and T3Is less than T2The controller sends an opening control signal to the fourth electromagnetic valve to enable the COCl of the controller to be opened2Introducing COCl into the substances in the second generation reactor2In a reaction protector, to be COCl2The COCl is introduced into all the substances in the second generation reactor2After the protector is reacted, the controller sends a closing control signal to the fourth electromagnetic valve to enable the COCl of the fourth electromagnetic valve to be closed2Second generation reactor to COCl2Closing a pipeline for introducing substances into the reaction protector;
s3i, the controller sends out opening control signal to the fifth on-off solenoid valve to make it COCl2Introduction of COCl2Distributor to treat COCl2All being passed through COCl2After the distributor, the controller sends a closing control signal to the fifth on-off solenoid valve to enable the controller to control the COCl2Reaction protector towards COCl2The distributor is filled with COCl2The pipe (2) is closed.
In a preferred embodiment of the present invention, the method for logging in by using the mobile intelligent handheld terminal comprises the following steps:
s11, the login client judges whether the login client remembers the login account and the login password to log in:
if the login mode is to remember the login account and the login password, executing step S12;
if the login mode is not to remember the login account and the login password, executing step S16;
s12, acquiring the unique ID code and the login symbol of the mobile intelligent handheld terminal, wherein the unique ID code of the mobile intelligent handheld terminal comprises one of a CPU unique ID number, a mainboard unique ID number and an RAM unique ID number; calculating the obtained unique ID code and login symbol of the mobile intelligent handheld terminal to obtain a login check code of the mobile intelligent handheld terminal;
judging whether the login check code obtained by calculation is consistent with the login check code stored on the login client side:
if the calculated login check code is consistent with the login check code stored in the login client, executing step S13;
if the calculated login check code is not consistent with the login check code stored on the login client, executing S16;
s13, acquiring the saved safe login account and the safe login password, and analyzing the acquired safe login account and the safe login password to obtain the login account and the login password;
s14, carrying out safe transmission processing on the obtained login account and login password to obtain a transmission login account and a transmission login password thereof;
s15, sending the obtained transmission login account and the obtained transmission login password to the cloud platform for verification;
s16, the login account inputted by the account input box and the login password inputted by the password input box are extracted, and the step S14 is executed.
In conclusion, due to the adoption of the technical scheme, the invention can treat COCl2And carrying out safety production and realizing safety login platform control.
Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.
Drawings
The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
FIG. 1 is a schematic block diagram of the connection of the present invention.
Detailed Description
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.
The invention discloses a platform system for generating phosgene, which comprises two buffer tanks and two Cl groups as shown in figure 12-CO mixer, two COCl2Generation reactor, COCl2Reaction protector, COCl2The system comprises a distributor, five flow electromagnetic valves, five on-off electromagnetic valves and M distribution electromagnetic valves; m is a positive integer greater than or equal to 1;
two buffer tanks are respectively Cl2Buffer tank and CO buffer tank, two Cl2respectively-CO mixers are Cl2-first mixer of CO and Cl2-second CO mixer, two COCl2The generation reactors are respectively COCl2First generation reactor and COCl2A second generation reactor; the five flow solenoid valves are respectively a first flow solenoid valve, a second flow solenoid valve, a third flow solenoid valve, a fourth flow solenoid valve and a fifth flow solenoid valve, and the five on-off solenoid valves are respectively a first on-off solenoid valve, a second on-off solenoid valve, a third on-off solenoid valve, a fourth on-off solenoid valve and a fifth on-off solenoid valve; the M distribution electromagnetic valves are respectively a first distribution electromagnetic valve, a second distribution electromagnetic valve, a third distribution electromagnetic valve, … … and an Mth distribution electromagnetic valve; cl2The pressure value of the buffer tank is 0.35MPa to 0.55MPa, preferably 0.45MPa, and the pressure difference is 0.03MPa to 0.05MPa, preferably 0.04 MPa; the pressure value of the CO buffer tank is 0.35MPa to 0.55MPa, preferably 0.45MPa, and the pressure difference is 0.03MPa to 0.05MPa, preferably 0.04 MPa. Into Cl2The amount of the buffer tank is 2235 kg/h-2385 kg/h, preferably 2355 kg/h; the amount of the CO entering the CO buffer tank is 958kg/h to 1047kg/h, preferably 1022 kg/h. Into COCl2The temperature of the mixed gas in the first generation reactor is 44.5-50 ℃, preferably 45 ℃, the water inlet temperature is 22-30 ℃, preferably 25 ℃, the water outlet temperature is 60-70 ℃, preferably 65 ℃, and the material temperature is controlled by controlling the water outlet flow. In COCl2In the second generation reactor, the water inlet temperature is 22-30 ℃, preferably 25 ℃, the water outlet temperature is 60-70 ℃, preferably 65 ℃, and the material temperature is controlled by controlling the water outlet flow. In COCl2The temperature of the reaction protector is reduced by surrounding with a tube nest of frozen toluene to ensure the COCl of the reaction protector2COCl in reaction protector2Is in liquid phase, and has a temperature of-7 ℃ to-3 ℃, preferably-5 ℃.
Cl2Cl of buffer tank2The inlet end of the pipeline is connected with the outlet end of the first flow electromagnetic valve, Cl2BufferCl of the tank2The outlet end of the pipeline is connected with the inlet end of a second flow electromagnetic valve, and the outlet end of the second flow electromagnetic valve is connected with Cl2-Cl of the CO first mixer2The inlet end of a CO pipeline of the CO buffer tank is connected with the inlet end of a third flow electromagnetic valve, the outlet end of the CO pipeline of the CO buffer tank is connected with the inlet end of a fourth flow electromagnetic valve, and the outlet end of the fourth flow electromagnetic valve is connected with Cl2-the CO inlet end of the first CO mixer is connected; cl2The mixing outlet of the first CO mixer is connected to the inlet of a first on-off solenoid valve, the outlet of which is connected to the COCl2The reaction inlet end of the first generation reactor is connected with the COCl2The reaction outlet end of the first generation reactor is connected with the reactant inlet end of the second electromagnetic opening valve, and the reactant outlet end of the second electromagnetic opening valve is connected with Cl2-the mixing inlet ends of the CO second mixers are connected; the inlet end of the first flow solenoid valve is conveyed to Cl from the outer pipeline of the park through the connecting pipeline2The inlet end of the second flow solenoid valve is connected with the CO which is sent out through a connecting pipeline.
Cl2Cl of buffer tank2The outlet end of the pipeline is also connected with the inlet end of a fifth flow electromagnetic valve, and the outlet end of the fifth flow electromagnetic valve is connected with Cl2-Cl of the second CO mixer2Inlet end connected, Cl2The mixing outlet end of the-CO second mixer is connected with the inlet end of a third cut-off solenoid valve, and the outlet end of the third cut-off solenoid valve is connected with the COCl2The reaction inlet end of the second generation reactor is connected with the COCl2The reaction outlet end of the second generation reactor is connected with the inlet end of a fourth electromagnetic valve, and the outlet end of the fourth electromagnetic valve is connected with the COCl2Inlet end connection of reaction protector, COCl2The outlet end of the reaction protector is connected with the inlet end of a fifth on-off solenoid valve, and the outlet end of the fifth on-off solenoid valve is connected with the COCl2COCl of distributor2The inlet ends are connected;
COCl2first COCl of distributor2COCl of distribution end and first distribution solenoid valve2Inlet end connected, COCl2Second COCl of distributor2A distribution end and a secondCOCl for dispensing solenoid valves2Inlet end connected, COCl2Third COCl of distributor2COCl of distribution end and third distribution solenoid valve2Inlet end connection, … …, COCl2Mth COCl of distributor2COCl of distribution end and Mth distribution solenoid valve2The inlet ends are connected; when its production line requires COCl2In the meantime, the COCl for connecting the pipeline with the first distribution solenoid valve2COCl for outlet end, second distribution solenoid valve2COCl of outlet end and third distribution solenoid valve2COCl for outlet port, … …, Mth distribution solenoid valve2One of the outlet ends is connected, and correspondingly controls the first distribution electromagnetic valve, the second distribution electromagnetic valve, the third distribution electromagnetic valve, … … and the Mth distribution electromagnetic valve to be opened so as to convey the required COCl to the production line2。
The first flow control end of the controller is connected with the flow control end of the first flow electromagnetic valve, the second flow control end of the controller is connected with the flow control end of the second flow electromagnetic valve, the third flow control end of the controller is connected with the flow control end of the third flow electromagnetic valve, the fourth flow control end of the controller is connected with the flow control end of the fourth flow electromagnetic valve, and the fifth flow control end of the controller is connected with the flow control end of the fifth flow electromagnetic valve; a first on-off control end of the controller is connected with a flow control end of the first on-off electromagnetic valve, a second on-off control end of the controller is connected with a flow control end of the second on-off electromagnetic valve, a third on-off control end of the controller is connected with a flow control end of the third on-off electromagnetic valve, a fourth on-off control end of the controller is connected with a flow control end of the fourth on-off electromagnetic valve, and a fifth on-off control end of the controller is connected with a flow control end of the fifth on-off electromagnetic valve; a first distribution control end of the controller is connected with a flow control end of a first distribution electromagnetic valve, a second distribution control end of the controller is connected with a flow control end of a second distribution electromagnetic valve, a third distribution control end of the controller is connected with a flow control end of a third distribution electromagnetic valve, … …, and an Mth distribution control end of the controller is connected with a flow control end of an Mth distribution electromagnetic valve;
and controlThe controller receives a control command sent by the cloud platform according to the data transmission module and generates the COCl2By COCl2The dispenser dispenses.
In a preferred embodiment of the invention, the method further comprises sending a control command to a controller of the mobile intelligent handheld terminal by logging in the cloud platform through the mobile intelligent handheld terminal.
In a preferred embodiment of the present invention, the data transmission module comprises a data transmission wireless module or/and a data transmission wired module;
the wireless data transmission end of the data transmission wireless module is connected with the wireless data transmission end of the controller, and the wired data transmission end of the data transmission wired module is connected with the wired data transmission end of the controller.
In a preferred embodiment of the present invention, the data transmission wireless module includes one or any combination of a WiFi data transmission wireless module, a 4G data transmission wireless module, a 5G data transmission wireless module, and a Lora data transmission wireless module;
the wireless data transmission end of the WiFi data transmission wireless module is connected with the WiFi wireless data transmission end of the controller, the wireless data transmission end of the 4G data transmission wireless module is connected with the 4G wireless data transmission end of the controller, the wireless data transmission end of the 5G data transmission wireless module is connected with the 5G wireless data transmission end of the controller, and the wireless data transmission end of the Lora data transmission wireless module is connected with the Lora wireless data transmission end of the controller.
In a preferred embodiment of the present invention, the data transmission wired module includes one or any combination of an RS485 data transmission wired module, a hundred mega RJ45 data transmission wired module, and a gigabit RJ45 data transmission wired module;
the wired data transmission end of the RS485 data transmission wired module is connected with the RS485 wired data transmission end of the controller, the wired data transmission end of the hundred-million RJ45 data transmission wired module is connected with the hundred-million RJ45 wired data transmission end of the controller, and the wired data transmission end of the kilomega RJ45 data transmission wired module is connected with the kilomega RJ45 wired data transmission end of the controller.
In a preferred embodiment of the present invention, further comprises Cl2The preheating tank, the CO preheating tank, the sixth on-off electromagnetic valve and the seventh on-off electromagnetic valve;
inlet end and Cl of sixth switching electromagnetic valve2Cl of buffer tank2The outlet end of the pipeline is connected, and the outlet end of the sixth switching-off electromagnetic valve is connected with Cl2Preheating inlet end of preheating tank, Cl2The preheating outlet end of the preheating tank is connected with the inlet end of the second flow electromagnetic valve; cl2The preheating outlet end of the preheating tank is also connected with the inlet end of a fifth flow electromagnetic valve; the inlet end of the seventh on-off electromagnetic valve is connected with the outlet end of the CO pipeline of the CO buffer tank, the outlet end of the seventh on-off electromagnetic valve is connected with the preheating inlet end of the CO preheating tank, and the preheating outlet end of the CO preheating tank is connected with the inlet end of the fourth flow electromagnetic valve. The concrete connection is as follows: cl2Cl of buffer tank2The inlet end of the pipeline is connected with the outlet end of the first flow electromagnetic valve, Cl2Cl of buffer tank2The outlet end of the pipeline is connected with the inlet end of a sixth on-off electromagnetic valve, and the outlet end of the sixth on-off electromagnetic valve is connected with Cl2Preheating inlet end of preheating tank, Cl2The preheating outlet end of the preheating tank is connected with the inlet end of a second flow electromagnetic valve, and the outlet end of the second flow electromagnetic valve is connected with Cl2-Cl of the CO first mixer2The inlet end of a CO pipeline of the CO buffer tank is connected with the inlet end of a third flow electromagnetic valve, the outlet end of the CO pipeline of the CO buffer tank is connected with the inlet end of a seventh on-off electromagnetic valve, the outlet end of the seventh on-off electromagnetic valve is connected with the preheating inlet end of a CO preheating tank, the preheating outlet end of the CO preheating tank is connected with the inlet end of a fourth flow electromagnetic valve, and the outlet end of the fourth flow electromagnetic valve is connected with Cl2-the CO inlet end of the first CO mixer is connected; cl2The mixing outlet of the first CO mixer is connected to the inlet of a first on-off solenoid valve, the outlet of which is connected to the COCl2The reaction inlet end of the first generation reactor is connected with the COCl2The reaction outlet end of the first generation reactor is connected with the reactant inlet end of the second electromagnetic opening valve, and the reactant outlet end of the second electromagnetic opening valve is connected with Cl2-CO secondThe mixing inlet ends of the mixers are connected;
Cl2the preheating outlet end of the preheating tank is also connected with the inlet end of a fifth flow electromagnetic valve, and the outlet end of the fifth flow electromagnetic valve is connected with Cl2-Cl of the second CO mixer2Inlet end connected, Cl2The mixing outlet end of the-CO second mixer is connected with the inlet end of a third cut-off solenoid valve, and the outlet end of the third cut-off solenoid valve is connected with the COCl2The reaction inlet end of the second generation reactor is connected with the COCl2The reaction outlet end of the second generation reactor is connected with the inlet end of a fourth electromagnetic valve, and the outlet end of the fourth electromagnetic valve is connected with the COCl2Inlet end connection of reaction protector, COCl2The outlet end of the reaction protector is connected with the inlet end of a fifth on-off solenoid valve, and the outlet end of the fifth on-off solenoid valve is connected with the COCl2COCl of distributor2The inlet ends are connected;
COCl2first COCl of distributor2COCl of distribution end and first distribution solenoid valve2Inlet end connected, COCl2Second COCl of distributor2COCl of distribution end and second distribution electromagnetic valve2Inlet end connected, COCl2Third COCl of distributor2COCl of distribution end and third distribution solenoid valve2Inlet end connection, … …, COCl2Mth COCl of distributor2COCl of distribution end and Mth distribution solenoid valve2The inlet ends are connected;
a first flow control end of the controller is connected with a flow control end of the first flow electromagnetic valve, a second flow control end of the controller is connected with a flow control end of the second flow electromagnetic valve, a third flow control end of the controller is connected with a flow control end of the third flow electromagnetic valve, a fourth flow control end of the controller is connected with a flow control end of the fourth flow electromagnetic valve, and a fifth flow control end of the controller is connected with a flow control end of the fifth flow electromagnetic valve; a first on-off control end of the controller is connected with a flow control end of a first on-off electromagnetic valve, a second on-off control end of the controller is connected with a flow control end of a second on-off electromagnetic valve, a third on-off control end of the controller is connected with a flow control end of a third on-off electromagnetic valve, a fourth on-off control end of the controller is connected with a flow control end of a fourth on-off electromagnetic valve, a fifth on-off control end of the controller is connected with a flow control end of a fifth on-off electromagnetic valve, a sixth on-off control end of the controller is connected with a flow control end of a sixth on-off electromagnetic valve, and a seventh on-off control end of the controller is connected with a flow control end of a seventh on-off electromagnetic valve; a first distribution control end of the controller is connected with a flow control end of the first distribution electromagnetic valve, a second distribution control end of the controller is connected with a flow control end of the second distribution electromagnetic valve, a third distribution control end of the controller is connected with a flow control end of the third distribution electromagnetic valve, … …, and an Mth distribution control end of the controller is connected with a flow control end of the Mth distribution electromagnetic valve.
In a preferred embodiment of the present invention, the apparatus further comprises a water circulator, wherein the first outlet end of the water circulator is connected with the COCl2The cooling inlet end of the first generation reactor is connected, the first inlet end of the water circulator is connected with the inlet end of an eighth on-off electromagnetic valve, and the outlet end of the eighth on-off electromagnetic valve is connected with the COCl2The cooling outlet end of the first generation reactor is connected; in COCl2A first temperature sensor is arranged in the first generation reactor, and the temperature data output end of the first temperature sensor is connected with the temperature data input end of the controller; the flow control end of the eighth on-off electromagnetic valve is connected with the eighth on-off control end of the controller;
second outlet end of water circulator and COCl2The cooling inlet end of the second generation reactor is connected, the second inlet end of the water circulator is connected with the inlet end of a ninth on-off solenoid valve, and the outlet end of the ninth on-off solenoid valve is connected with the COCl2The cooling outlet end of the second generation reactor is connected; in COCl2A second temperature sensor is arranged in the second generation reactor, and the temperature data output end of the second temperature sensor is connected with the temperature data input end of the controller; and the flow control end of the ninth on-off electromagnetic valve is connected with the ninth on-off control end of the controller.
In a preferred embodiment of the present invention, a first pressure sensor or/and a third temperature sensor are disposed in the CO preheating tank, a pressure data output end of the first pressure sensor is connected to a first pressure data input end of the controller, a temperature data output end of the third temperature sensor is connected to a third temperature data input end of the controller, a warming inlet end of the CO preheating tank is connected to a third outlet end of the water circulator, a warming outlet end of the CO preheating tank is connected to an inlet end of a tenth on-off solenoid valve, an outlet end of the tenth on-off solenoid valve is connected to a third inlet end of the water circulator, and a flow control end of the tenth on-off solenoid valve is connected to a tenth on-off control end of the controller;
in Cl2A second pressure sensor or/and a fourth temperature sensor are/is arranged in the preheating tank, the pressure data output end of the second pressure sensor is connected with the second pressure data input end of the controller, the temperature data output end of the fourth temperature sensor is connected with the fourth temperature data input end of the controller, and Cl is added2The heating inlet end of the preheating tank is connected with the fourth outlet end of the water circulator, and Cl2The heating outlet end of the preheating tank is connected with the inlet end of an eleventh on-off electromagnetic valve, the outlet end of the eleventh on-off electromagnetic valve is connected with the fourth inlet end of the water circulator, and the flow control end of the eleventh on-off electromagnetic valve is connected with the eleventh on-off control end of the controller. Preset of Cl2The temperature threshold is 35-50 ℃, preferably 50 ℃, the water inlet temperature is 36.5-51.5 ℃, preferably, the water inlet temperature is 51 ℃, the water outlet temperature is 35-51 ℃, and preferably, the water outlet temperature is 50 ℃; the CO preheating temperature threshold is 20-30 ℃, preferably 25 ℃; the water inlet temperature is 21.5-32 ℃, the water outlet temperature is 23-31 ℃, and the preferred water outlet temperature is 25 ℃. The water circulator may be Cl2Preheating tank, CO preheating tank, Cl2-first mixer of CO and Cl2The CO second mixer provides water circulation at different temperatures.
The invention also discloses a control method for generating the phosgene platform system, which comprises the following steps:
s1, logging in a cloud platform by using the mobile intelligent handheld terminal;
s2, after logging in the cloud platform, changing the control parameters, and sending the changed control parameters to the controller;
and S3, after the controller verifies, taking the changed control parameters as the control parameters of the current operation and the subsequent operation.
In a preferred embodiment of the present invention, in step S3, the method for operating when the controller does not receive the control parameter modification includes the following steps:
s3a, initializing the system, the initialization including:
the controller respectively sends closing control signals to the first flow electromagnetic valve to the fifth flow electromagnetic valve, sends closing control signals to the first on-off electromagnetic valve to the eleventh on-off electromagnetic valve and sends closing control signals to the first distribution electromagnetic valve to the Mth distribution electromagnetic valve; the pipeline is in a cut-off state;
s3b, if the controller receives the generated COCl2Triggering the control signal, the controller respectively sends out opening control signals to the first flow electromagnetic valve and the third flow electromagnetic valve, and the control signal is controlled to enter Cl2Cl in buffer tank2The amount of CO and the amount of CO entering the CO surge tank;
when the first flow solenoid valve and/or the third flow solenoid valve T are opened1After min, the T1The controller respectively sends opening control commands to a tenth on-off solenoid valve and an eleventh on-off solenoid valve to enable circulating water in the water circulator to circulate Cl pairs2Preheating the preheating tank and the CO preheating tank;
s3c, when it entered Cl2Cl in buffer tank2In an amount equal to the predetermined Cl2At threshold, the controller sends a close signal to its first flow solenoid valve, no longer to Cl2Conveying Cl in buffer tank2(ii) a When the amount of CO entering the CO buffer tank is equal to the preset CO threshold value, the controller sends a closing signal to the third flow electromagnetic valve of the controller, and CO is not conveyed into the CO buffer tank any more;
s3d, when the controller receives that the temperature value collected by the fourth temperature sensor is equal to the preset Cl2When the temperature is higher than the threshold value, the controller sends an opening control signal to a sixth on-off electromagnetic valve to enable the sixth on-off electromagnetic valve to be Cl2Cl in buffer tank2Into Cl2Preheating in a preheating tank; when the controllerThe temperature value acquired by the fourth temperature sensor is equal to the preset Cl2Preheating temperature threshold, Cl2The preheating temperature threshold is larger than the preset Cl2When the temperature is in the threshold value, the controller sends an opening control signal to the second flow electromagnetic valve to ensure that the preheated Cl is heated2Into Cl2CO first mixer and as it enters Cl2-Cl of the CO first mixer2In an amount equal to the predetermined Cl2The mixing threshold, then the controller sends a closing control signal to its second flow solenoid valve, no longer to Cl2-conveying Cl in a CO first mixer2;
When the controller receives that the temperature value acquired by the third temperature sensor is equal to the preset CO temperature threshold value, the controller sends an opening control signal to a seventh on-off electromagnetic valve of the controller, so that CO in a CO buffer tank enters a CO preheating tank for preheating; when the temperature value acquired by the third temperature sensor and received by the controller is equal to the preset CO preheating temperature threshold value which is greater than the preset CO temperature threshold value, the controller sends an opening control signal to a fourth flow electromagnetic valve of the controller, so that the preheated CO enters Cl2CO first mixer and as it enters Cl2-the CO quantity of the first CO mixer is equal to the preset CO mixing threshold, the controller sends a closing control signal to its fourth flow solenoid valve, no longer to Cl2-transporting CO in a CO first mixer;
s3e, to Cl2And CO in Cl2After sufficient mixing in the first CO mixer, the controller sends an opening control signal to the first on-off solenoid valve to release Cl2-Cl in the first CO mixer2With CO into COCl2The first generation reactor carries out reaction; to be Cl2-Cl in the first CO mixer2The mixed gas with CO is discharged into COCl2After the first generation reactor, the controller sends a closing control signal to a first on-off electromagnetic valve of the first generation reactor to enable the first on-off electromagnetic valve to be Cl2First mixer of CO to COCl2Introducing Cl into the first generation reactor2Closing a pipeline of the mixed gas with CO;
s3f, when the controller receives that the temperature value collected by the first temperature sensor is greater than or equal to the preset first temperature threshold value,the controller sends an opening control signal to an eighth on-off electromagnetic valve of the controller to enable circulating water in the water circulator to circulate the COCl2Cooling the first generation reactor; when reaction T is carried out2After min time, said T2Is greater than T1The controller sends an opening control signal to the second electromagnetic opening valve to enable the COCl of the controller to be in a COCl state2Introducing Cl into the residual gas which is not reacted in the first generation reactor2In a second CO mixer, to be COCl2All the unreacted residual gas in the first generation reactor is introduced with Cl2After the second mixer of CO, the controller sends a closing control signal to its second on-off solenoid valve, causing its COCl2First generation reactor to Cl2The pipeline for feeding the unreacted residual gas into the CO second mixer is closed;
s3g, the controller sends an opening control signal to the fifth flow electromagnetic valve to ensure that the preheated Cl is ensured2Into Cl2-CO second mixer and as it enters Cl2-Cl of the second CO mixer2In an amount equal to the predetermined Cl2The second mixing threshold value, the controller sends a closing control signal to the fifth flow electromagnetic valve of the controller, and the second mixing threshold value is not sent to Cl2-CO second Mixer for Cl2(ii) a To be Cl2-after the gas in the second CO mixer is sufficiently mixed, the controller sends an opening control signal to the third electromagnetic valve to open the third electromagnetic valve, so as to enable Cl2The mixed gas in the second CO mixer is discharged into the COCl2The second generation reactor carries out reaction; to be Cl2The mixed gas in the second CO mixer is discharged into the COCl2After the second generation reactor, the controller sends a closing control signal to a third cut-off solenoid valve of the second generation reactor to enable the third cut-off solenoid valve to be Cl2Second mixer of CO to COCl2Closing a pipeline for introducing mixed gas into the second generation reactor;
s3h, when the controller receives that the temperature value acquired by the second temperature sensor is greater than or equal to a preset first temperature threshold value, the controller sends an opening control signal to a ninth on-off solenoid valve of the controller to enable circulating water in the water circulator to circulate to COCl2Cooling the second generation reactor; when reaction T is carried out3After min time, said T3Is greater than T1Is a positive number of, and T3Is less than T2The controller sends an opening control signal to the fourth electromagnetic valve to enable the COCl of the controller to be opened2Introducing COCl into the substances in the second generation reactor2In a reaction protector, to be COCl2The COCl is introduced into all the substances in the second generation reactor2After the protector is reacted, the controller sends a closing control signal to the fourth electromagnetic valve to enable the COCl of the fourth electromagnetic valve to be closed2Second generation reactor to COCl2Closing a pipeline for introducing substances into the reaction protector;
s3i, the controller sends out opening control signal to the fifth on-off solenoid valve to make it COCl2Introduction of COCl2Distributor to treat COCl2All being passed through COCl2After the distributor, the controller sends a closing control signal to the fifth on-off solenoid valve to enable the controller to control the COCl2Reaction protector towards COCl2The distributor is filled with COCl2The pipe (2) is closed.
In a preferred embodiment of the present invention, step S1 includes the following steps:
s11, the login client judges whether the login client remembers the login account and the login password to log in:
if the login mode is to remember the login account and the login password, executing step S12;
if the login mode is not to remember the login account and the login password, executing step S16;
s12, acquiring the unique ID code of the mobile intelligent handheld terminal and the uniform resource locator of the login website, wherein the unique ID code of the mobile intelligent handheld terminal comprises one of a CPU unique ID number, a mainboard unique ID number and an RAM unique ID number; calculating the obtained unique ID code of the mobile intelligent handheld terminal and the uniform resource locator of the login website to obtain a login check code of the mobile intelligent handheld terminal; the obtaining mode of the login check code is as follows:
wherein, Lvc represents the calculated login check code;
A1a unique ID code representing the mobile intelligent handheld terminal; the mobile intelligent handheld terminal is not limited to a smart phone, a tablet personal computer and a wearable watch, and can also be an all-in-one machine or a desktop machine.
B1A uniform resource locator representing a logged-in web address;
[, ] represent two parameters of the input Hash function;
h < > represents a Hash function;
-representing a connector; in this embodiment, for example, a unique ID code (motherboard unique ID number) a of a mobile smart handheld terminal1234760761688271, uniform resource locator B of the logged-on web site1Html is https:// www.cnipa.gov.cn/col/col2452/index.
It is composed of
The Hash function of the Hash function adopts an MD5 algorithm (can also adopt SHA256 or SHA1) to obtain a 16-system lower-case login check code, namely:
Lvc=d8e032990e082ac657bdc3c7f66b2dd0,
the login check code only has one or any combination of numbers 0-9 and lower case letters a-f, but does not have capital letters A-Z and lower case letters g-Z; therefore, the code is converted into a 62-system login check code, and the cracking difficulty is enhanced.
And Lvc (62) ═ 6BeNFY4bOV7r5jUBTCCeBi, and Lvc (62) represents a 62-system login check code, so that the safety factor is improved.
Judging whether the login check code obtained by calculation is consistent with the login check code stored on the login client side:
if the calculated login check code is consistent with the login check code stored in the login client, executing step S13;
if the calculated login check code is not consistent with the login check code stored on the login client, executing S16;
s13, acquiring the saved safe login account and the safe login password, and analyzing the acquired safe login account and the safe login password to obtain the login account and the login password; the obtaining mode of the login account is as follows:
decrypting the secure login account number through a secret key (key) to obtain a decrypted secure login account number, and decrypting the decrypted secure login account number by using a private key of a user of the secure login account number to obtain a login account number of the secure login account number;
the login password is obtained in the following mode:
decrypting the secure login password by the key to obtain a decrypted secure login password, and decrypting the decrypted secure login password by using a private key of a user to obtain a login password;
s14, carrying out safe transmission processing on the obtained login account and the login password to obtain a transmission login account and a transmission login password thereof, wherein the transmission login account is obtained by the following method:
encrypting the login account by using the public key of the cloud platform to obtain an encrypted login account; encrypting the obtained encrypted login account by using the key thereof to obtain a transmission login account thereof;
the method for obtaining the transmission login password comprises the following steps:
encrypting the login password by using the public key of the cloud platform to obtain an encrypted login account; encrypting the obtained encrypted login password by using the key thereof to obtain a transmission login password thereof;
s15, sending the obtained transmission login account and the obtained transmission login password to the cloud platform for verification;
s16, extracting the login account inputted by the account input box and the login password inputted by the password input box, and executing the step S14; the login safety is ensured, the mobile intelligent handheld terminal is prevented from being lost, login information of a login client on the mobile intelligent handheld terminal is copied to other equipment for login, and the login by a fake name is effectively prevented.
Or/and if the login account is the login account for the first time in the step S12, the method includes the following steps:
s121, the login client judges whether the login client successfully logs in the cloud platform:
if the login of the client to the cloud platform is successful, executing the next step;
if the login of the login client to the cloud platform fails, waiting for the login of the login client to succeed; executing the next step;
s122, acquiring the unique ID code and the login symbol (namely the uniform resource locator of the login website) of the mobile intelligent handheld terminal, wherein the unique ID code of the mobile intelligent handheld terminal comprises one of a CPU unique ID number, a mainboard unique ID number and an RAM unique ID number; calculating the obtained unique ID code of the mobile intelligent handheld terminal and the uniform resource locator of the login website, and storing the obtained login check code on the login client; the obtaining mode of the login check code is as follows:
wherein, Lvc represents the calculated login check code;
A1a unique ID code representing the mobile intelligent handheld terminal;
B1a uniform resource locator representing a logged-in web address;
[, ] represent two parameters of the input Hash function;
h < > represents a Hash function;
-representing a connector;
s123, extracting the login account and the login password input by the account input box, performing security processing on the extracted login account and the extracted login password to obtain a secure login account and a secure login password, and storing the obtained secure login account and the secure login password in the login client; the method for obtaining the safe login account number comprises the following steps:
encrypting the login account by using a public key of a user to obtain an encrypted security account, and encrypting the encrypted security account by using a secret key to obtain a security login account;
the method for obtaining the safe login password comprises the following steps:
encrypting the login password by using a public key of a user to obtain an encrypted security password of the login password, and encrypting the encrypted security password by using a secret key to obtain a secure login password of the login password; the mobile intelligent handheld terminal login client remembers the account and the password for the first time to carry out safety processing, even if the information is copied, the login account information and the password information are difficult to obtain, and the safety factor is improved.
Or/and the following steps are included in the step S2:
s21, the cloud platform decodes the received transmission login account and the transmission login password to obtain a cloud login account and a cloud login password; the method for obtaining the cloud login account number comprises the following steps:
decoding the received transmission login account by using a key to obtain a cloud decoding transmission login account of the transmission login account, and decoding the obtained cloud decoding transmission login account by using a private key of a cloud platform of the cloud decoding transmission login account to obtain a cloud login account of the cloud decoding transmission login account;
the method for obtaining the cloud login password comprises the following steps:
decoding the received transmission login password by using a key to obtain a cloud decoding transmission login password of the transmission login password, and decoding the obtained cloud decoding transmission login password by using a private key of a cloud platform of the cloud transmission login password to obtain a cloud login password of the cloud decoding transmission login password;
s22, performing account and password verification processing on the obtained cloud login account and cloud login password, wherein the account verification processing mode on the cloud login account is as follows:
accountnumber=H<account>,
wherein, the accountnumber represents the cloud check login account obtained through calculation;
the account represents a cloud login account;
h < > represents a Hash function;
the password verification processing mode of the cloud login password is as follows:
passwordnumber=H<password>,
wherein, password represents the cloud check login password obtained by calculation;
password represents a cloud login password;
h < > represents a Hash function;
s23, judging whether the cloud check login account and the cloud check login password exist in the cloud platform:
s231, judging whether the cloud check login account exists in the cloud platform:
if the cloud verification login account exists in the cloud platform, executing the next step;
if the cloud verification login account does not exist in the cloud platform, prompting that the account input in the account input box does not exist;
s232, determine whether the cloud verification login password in step S22 is consistent with the cloud verification login password corresponding to the cloud verification login account stored on the cloud platform:
if the cloud verification login password in the step S22 is consistent with the cloud verification login password corresponding to the cloud verification login account stored on the cloud platform, the login is successful;
if the cloud verification login password in the step S22 is not consistent with the cloud verification login password corresponding to the cloud verification login account stored on the cloud platform, the login fails. The security verification of the cloud platform can ensure the security of the account and the password of the user even if the account and the password stored in the cloud platform are leaked.
In a preferred embodiment of the present invention, step S2 includes the following steps:
s2a, the cloud platform requests the update code from the controller, and the manner of the update code generated by the controller is as follows:
Update code=H<identity-time>,
wherein, Update code represents the updating code generated by the controller;
identity represents a unique ID number of one of a WiFi data transmission wireless module, a 4G data transmission wireless module, a 5G data transmission wireless module, a Lora data transmission wireless module, an RS485 data transmission wired module, a hundred-megabyte RJ45 data transmission wired module and a kilomega RJ45 data transmission wired module;
h < > represents a Hash function;
-representing a connector;
time represents the time when the controller receives the cloud platform update code request; in this embodiment, for example, the unique ID number identity of the WiFi data transmission wireless module is 55B89ABF17C4, the time when the controller receives the cloud platform update code request is 2021, 07, 13 min 18 sec 0857 ms, 13 th, and the time is now formatted as 202107071313180857.
The Hash function of the Hash function adopts an MD5 algorithm (can also adopt SHA256 or SHA1) to obtain an update code of 16-system lower case, namely:
Update code=6f9d7e718dd9180296920bc280c14a5e,
because the results obtained by adopting the MD5 algorithm are all fixed 32-bit 16-system numerical values, subsequent comparison is inconvenient; therefore, the updating code is converted into the 62-system updating code, the length of the updating code is shortened, and the data transmission and the efficiency improvement are facilitated.
Update code (62) ═ 3oC7DElLG2S9fq3nRF7RU2, and Update code (62) indicates an Update code in the 62 system.
As can be seen from the above, this update code is shortened by 10 bits, and other update codes calculate the number of shortened bits.
Covering the generated update code with the update code covered last time to serve as a comparison code, and sending the update code to the cloud platform;
s2b, the cloud platform stores the changed control parameters to be sent in a control parameter text, the cloud platform stores the received update codes in the positions of the update codes of the control parameter text after receiving the update codes, and the control parameter text added with the control parameters and the update codes is used as a file to be compressed; the control parameters thereof not being limited to including the preset Cl2Threshold, preset CO threshold, preset Cl2Mixing threshold, presetting first temperature threshold, presetting Cl2Temperature threshold, preset Cl2Temperature threshold, preset Cl2One or any combination of the second mixing thresholds may also be includedIncluding pressure, differential pressure, flow rate, etc.
S2c, compressing the file to be compressed to obtain a compressed file thereof, and decompressing the compressed file to obtain a decompressed file thereof; judging whether the decompressed files only have one file or not;
if only one file exists in the decompressed files, the compressed files are files to be sent;
if more than one file in the file is decompressed, opening the compressed file to reserve the control parameter text of the compressed file, and deleting other files, wherein the other files comprise configuration files or/and hidden files; taking the compressed file which reserves the control parameter text as a file to be sent; therefore, the method is beneficial to preventing the files generated in the compression process from increasing the transmission quantity, improving the transmission efficiency and reducing the waste of the storage space of the controller.
And S2d, sending the file to be sent to the controller for verification.
In a preferred embodiment of the present invention, step S3 includes the following steps:
s31, the controller decompresses the received sending file to obtain the local decompressed file, extracts the updating code in the local decompressed file as the comparison code;
s32, judging whether the comparison code is the same as the comparison code:
if the comparison code is the same as the comparison code, executing the next step;
if the comparison code is different from the comparison code, the controller requests the cloud platform to resend the changed control parameters;
and S33, extracting the control parameters in the local decompressed file for parameter updating.
While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.
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