CN110864222A - Centralized liquid supply system for automobile assembly workshop - Google Patents

Abstract

The invention provides a centralized liquid supply system for an automobile assembly workshop, which comprises a controller, a brake liquid subsystem, a coolant subsystem and a refrigerant subsystem, wherein a brake liquid control output end of the controller is connected with a control input end of the brake liquid subsystem, a coolant liquid control output end of the controller is connected with a control input end of the coolant liquid subsystem, and a coolant control output end of the controller is connected with a control input end of the refrigerant subsystem. The brake fluid, the cooling fluid, the refrigerant and other various liquids can be simultaneously conveyed, conveying pipelines of the liquids cannot influence each other, the liquids are conveyed independently, the system is stable, and the working efficiency is high.

Description

Centralized liquid supply system for automobile assembly workshop

Technical Field

The invention relates to the technical field of material conveying, in particular to a centralized liquid supply system for an automobile assembly workshop.

Background

The centralized liquid supply system can provide remote delivery according to the needs of users, remotely deliver liquid from the liquid storage tank to the use appointed by the users at a certain pressure and flow rate, and is generally applied to various filling devices in a final assembly workshop, a vehicle-out filling point of the final assembly workshop and the like. The conveying medium comprises various liquids such as fuel oil (gasoline and diesel oil), brake fluid, refrigerant, engine oil, transmission engine oil, gear oil, power steering fluid and the like, so that a centralized liquid supply system capable of stably conveying various liquids is urgently needed.

Disclosure of Invention

The invention aims to at least solve the technical problems in the prior art, and particularly provides a centralized liquid supply system for an automobile assembly workshop, which can stably convey various liquids.

In order to achieve the purpose, the invention provides a centralized liquid supply system for an automobile assembly workshop, which comprises a controller, a brake liquid subsystem, a cooling liquid subsystem and a refrigerant subsystem, wherein the brake liquid control output end of the controller is connected with the control input end of the brake liquid subsystem, the cooling liquid control output end of the controller is connected with the control input end of the cooling liquid subsystem, and the refrigerant control output end of the controller is connected with the control input end of the cooling liquid subsystem.

In the scheme, the method comprises the following steps: the brake fluid subsystem comprises a first brake fluid storage tank, a first brake fluid suction pump is arranged in the first brake fluid storage tank and is communicated with a brake fluid suction hose, the other end of the brake fluid suction hose is communicated with a material inlet of a first brake fluid electromagnetic angle seat valve, and a signal input end of the first brake fluid electromagnetic angle seat valve is connected with a signal output end of the first brake fluid storage valve of the controller; a material outlet of the first brake fluid electromagnetic angle seat valve is communicated with a material inlet of a first brake fluid infusion pump, the material outlet of the first brake fluid infusion pump is communicated with a material inlet of a brake fluid supply end valve through a brake fluid infusion pipe, a brake fluid pressure detector is arranged on the brake fluid infusion pipe, a signal output end of the brake fluid pressure detector is connected with a brake fluid pressure signal input end of a controller, and the material outlet of the brake fluid supply end valve is communicated with a brake fluid filling machine;

the first brake fluid infusion pump is a pneumatic diaphragm pump, the driving gas input end of the first brake fluid infusion pump is connected with one end of the first brake fluid gas transmission branch pipe, the other end of the first brake fluid gas transmission branch pipe is communicated with the tail end of the brake fluid gas transmission main pipe, and the starting end of the brake fluid gas transmission main pipe is connected with the compressed air pipe; and the brake fluid pneumatic triple piece, the brake fluid pump electromagnetic valve and the brake fluid idle driving prevention protector are sequentially arranged on the brake fluid gas transmission main pipe along the airflow direction.

In the scheme, the method comprises the following steps: the brake fluid subsystem is also provided with a second brake fluid storage tank, a second brake fluid suction pump is arranged in the second brake fluid storage tank, the second brake fluid suction pump is also communicated with a second brake fluid electromagnetic angle seat valve through a brake fluid suction hose, and the second brake fluid electromagnetic angle seat valve is communicated with the starting end of a brake fluid supply pipe; the signal input end of the second brake fluid electromagnetic angle seat valve is connected with the signal output end of a second brake fluid storage valve of the controller; a brake fluid flow detector is arranged on the brake fluid supply pipe, and the signal output end of the brake fluid flow detector is connected with the brake fluid flow signal input end of the controller; the first brake fluid storage tank and the second brake fluid storage tank are mounted in a one-use-one-standby mode;

the brake fluid subsystem further comprises a brake fluid barrel changing audible and visual alarm, and the signal input end of the brake fluid barrel changing audible and visual alarm is connected with the brake fluid alarm signal output end of the controller.

In the scheme, the method comprises the following steps: and drying cylinders are arranged on the air vents of the first brake fluid storage tank and the second brake fluid storage tank.

In the scheme, the method comprises the following steps: the cooling liquid subsystem comprises a cooling liquid unloading unit and a cooling liquid station area conveying unit;

the cooling liquid unloading unit comprises a cooling liquid conveying subunit and a cooling liquid gas recovery subunit;

the cooling liquid delivery sub-unit comprises a cooling liquid unloading connector, and is communicated with a cooling liquid tank truck through a cooling liquid unloading connector material inlet; a material outlet of the first cooling liquid electromagnetic angle seat valve is communicated with a material inlet of a first cooling liquid unloading pump through a cooling liquid station area conveying main pipe, a cooling liquid unloading flow detector is arranged on the cooling liquid station area conveying main pipe, a signal output end of the cooling liquid unloading flow detector is connected with a cooling liquid unloading signal input end of a controller, the material outlet of the first cooling liquid unloading pump is communicated with two cooling liquid stainless steel storage tanks through two cooling liquid station area conveying branch pipes, cooling liquid level meters are arranged in the two cooling liquid stainless steel storage tanks, and a signal output end of the cooling liquid level meter is connected with a cooling liquid level signal input end of the controller;

the first cooling liquid unloading pump is a pneumatic diaphragm pump, the driving air input end of the first cooling liquid unloading pump is connected with one end of a first cooling liquid unloading air conveying branch pipe, the other end of the first cooling liquid unloading air conveying branch pipe is communicated with the tail end of a cooling liquid unloading air conveying main pipe, and the starting end of the cooling liquid unloading air conveying main pipe is connected with a compressed air pipe; the cooling liquid unloading and gas transmission main pipe is sequentially provided with a cooling liquid unloading pneumatic triple piece, a cooling liquid unloading pump electromagnetic valve and a cooling liquid unloading idle-run protector along the airflow direction; and the signal input end of the electromagnetic valve of the cooling liquid unloading pump is connected with the driving signal output end of the cooling liquid station pump of the controller.

In the scheme, the method comprises the following steps: the cooling liquid and gas recovery sub-unit comprises cooling liquid and gas recovery pipes communicated with the tops of the two cooling liquid stainless steel storage tanks, the other ends of the cooling liquid and gas recovery pipes are communicated with a material inlet of a second cooling liquid electromagnetic angle seat valve, and the signal input end of the second cooling liquid electromagnetic angle seat valve is connected with the cooling liquid recovery signal output end of the controller; and a material outlet of the second cooling liquid electromagnetic angle seat valve is connected with a cooling liquid gas recovery joint and is communicated with a cooling liquid gas inlet of the cooling liquid tank truck through the cooling liquid gas recovery joint.

The cooling liquid gas recovery subunit is used for recovering the cooling liquid which is volatilized to form a gas state into the cooling liquid tank truck for recovery, so that the loss of the cooling liquid is reduced, and meanwhile, the gas formed by the cooling liquid is prevented from leaking in the air, and the environmental pollution is avoided.

In the scheme, the method comprises the following steps: the cooling liquid station area conveying unit comprises a cooling liquid conveying pipe, the initial end of the cooling liquid conveying pipe is communicated with two conveying ports at the bottom of the cooling liquid stainless steel storage tank, the tail end of the cooling liquid conveying pipe is communicated with a material inlet of a first cooling liquid conveying pump, a material outlet of the first cooling liquid conveying pump is communicated with a material inlet of a third cooling liquid electromagnetic angle seat valve through a cooling liquid station area conveying pipe, a material outlet of the third cooling liquid electromagnetic angle seat valve is communicated with a cooling liquid filling machine, and a signal input end of the third cooling liquid electromagnetic angle seat valve is connected with a cooling liquid filling signal output end of a controller; a cooling liquid station area conveying pressure detector is arranged on the cooling liquid station area conveying pipe, the signal output end of the cooling liquid station area conveying pressure detector is connected with the cooling liquid station area conveying pressure signal input end of the controller, and the pipe pressure conveyed by the cooling liquid station area is monitored in real time through the cooling liquid station area conveying pressure detector;

the first cooling liquid infusion pump is a pneumatic diaphragm pump, the driving gas input end of the first cooling liquid infusion pump is connected with one end of a gas transmission branch pipe of the first cooling liquid station area, the other end of the gas transmission branch pipe of the first cooling liquid station area is communicated with the tail end of a gas transmission main pipe of the cooling liquid station area, and the start end of the gas transmission main pipe of the cooling liquid station area is connected with a compressed air pipe; a cooling liquid pneumatic triple piece, a cooling liquid infusion pump electromagnetic valve and a cooling liquid idle driving prevention protector are sequentially arranged on the cooling liquid station area gas transmission main pipe along the airflow direction; and the signal input end of the electromagnetic valve of the cooling liquid infusion pump is connected with the driving signal output end of the cooling liquid station area pump of the controller.

In the scheme, the method comprises the following steps: the cooling liquid subsystem further comprises a cooling liquid standby conveying unit, the cooling liquid standby conveying unit comprises a first cooling liquid standby liquid storage tank, a first cooling liquid suction pump is arranged in the first cooling liquid standby liquid storage tank and is communicated with a cooling liquid suction hose, the other end of the cooling liquid suction hose is communicated with a fourth cooling liquid electromagnetic angle seat valve material inlet, a signal input end of the fourth cooling liquid electromagnetic angle seat valve is connected with a signal output end of a first cooling liquid standby liquid storage valve of a controller, a material outlet of the fourth cooling liquid electromagnetic angle seat valve is communicated with the beginning end of a cooling liquid standby liquid storage main pipe through a first cooling liquid standby liquid storage branch pipe, the tail end of the cooling liquid standby liquid storage tank is communicated with a material inlet of the first cooling liquid standby liquid infusion pump, and the material outlet of the first cooling liquid standby infusion pump is communicated with a material inlet of a third cooling liquid electromagnetic angle seat valve;

the first cooling liquid standby infusion pump is a pneumatic diaphragm pump, the driving air input end of the first cooling liquid standby infusion pump is connected with one end of a first cooling liquid standby air delivery branch pipe, the other end of the first cooling liquid standby air delivery branch pipe is communicated with the tail end of a cooling liquid standby air delivery main pipe, and the starting end of the cooling liquid standby air delivery main pipe is connected with a compressed air pipe; a cooling liquid standby pneumatic triple piece, a cooling liquid standby infusion pump electromagnetic valve and a cooling liquid standby idle-run prevention protector are sequentially arranged on the cooling liquid standby gas transmission main pipe along the airflow direction; the signal input end of the electromagnetic valve of the cooling liquid standby infusion pump is connected with the driving signal output end of the cooling liquid standby pump of the controller.

In the scheme, the method comprises the following steps: the refrigerant subsystem comprises a first refrigerant steel cylinder, a first steel cylinder scale is arranged at the bottom of the first refrigerant steel cylinder, the signal output end of the first steel cylinder scale is connected with the weight signal input end of a first steel cylinder of the controller, the first refrigerant steel cylinder is communicated with one end of a first refrigerant liquid supply branch pipe, a first refrigerant electromagnetic angle seat valve is arranged on the first refrigerant liquid supply branch pipe, and the signal input end of the first refrigerant electromagnetic angle seat valve is connected with the signal output end of a first refrigerant valve of the controller; the other end of the first refrigerant liquid supply branch pipe is connected with one end of a refrigerant liquid supply main pipe, the other end of the refrigerant liquid supply main pipe is communicated with a first plunger pump material inlet, a first plunger pump material outlet is communicated with a third refrigerant electromagnetic angle seat valve material inlet through a refrigerant conveying main pipe, a second refrigerant pressure sensor is arranged on the refrigerant conveying main pipe, a signal output end of the second refrigerant pressure sensor is connected with a refrigerant tail end pressure sensing signal input end of a controller, and a third refrigerant electromagnetic angle seat valve is communicated with an inlet of a refrigerant filling machine; the other end of the refrigerant liquid supply main pipe is communicated with a material inlet of a refrigerant overpressure drainage valve, and a material outlet of the refrigerant overpressure drainage valve is communicated with a material inlet of the refrigerant conveying main pipe;

the first plunger pump is a pneumatic plunger pump, the driving air input end of the first plunger pump is connected with one end of a first refrigerant air transmission branch pipe, the other end of the first refrigerant air transmission branch pipe is communicated with the tail end of a refrigerant air transmission main pipe, and the starting end of the refrigerant air transmission main pipe is connected with a compressed air pipe; the refrigerant gas transmission main pipe is sequentially provided with a refrigerant pneumatic triple piece, a refrigerant electromagnetic valve and a refrigerant idle-run prevention protector along the airflow direction.

In the scheme, the method comprises the following steps: the refrigerant subsystem comprises a second refrigerant steel cylinder, a second steel cylinder scale is arranged at the bottom of the second refrigerant steel cylinder, the signal output end of the second steel cylinder scale is connected with the weight signal input end of the second steel cylinder of the controller, the second refrigerant steel cylinder is communicated with one end of a second refrigerant liquid supply branch pipe, a second refrigerant electromagnetic angle seat valve is arranged on the second refrigerant liquid supply branch pipe, and the signal input end of the second refrigerant electromagnetic angle seat valve is connected with the signal output end of the second refrigerant steel cylinder valve of the controller; the other end of the second refrigerant liquid supply branch pipe is also connected with one end of the refrigerant liquid supply main pipe; the first refrigerant steel cylinder and the second refrigerant steel cylinder are arranged in a standby mode;

the refrigerant subsystem further comprises a refrigerant barrel-changing audible and visual alarm, and the signal input end of the refrigerant barrel-changing audible and visual alarm is connected with the refrigerant alarm signal output end of the controller.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that: the brake fluid, the cooling fluid, the refrigerant and other various liquids can be simultaneously conveyed, conveying pipelines of the liquids cannot influence each other, the liquids are conveyed independently, the system is stable, and the working efficiency is high.

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 system diagram of the present invention;

FIG. 2 is a schematic diagram of the brake fluid subsystem of the present invention;

FIG. 3 is a schematic diagram of the refrigerant subsystem according to the present invention;

FIG. 4 is a schematic diagram of the coolant subsystem of the present invention;

FIG. 5 is a schematic structural diagram of a windshield washer fluid subsystem according to 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.

As shown in fig. 1-5, the centralized liquid supply system for the automobile assembly workshop comprises a controller, a brake fluid subsystem, a coolant subsystem and a refrigerant subsystem, wherein a brake fluid control output end of the controller is connected with a control input end of the brake fluid subsystem, a coolant control output end of the controller is connected with a control input end of the coolant subsystem, and a refrigerant control output end of the controller is connected with a control input end of the refrigerant subsystem.

The brake fluid subsystem comprises a first brake fluid storage tank 101a, a first brake fluid suction pump 102a is arranged in the first brake fluid storage tank 101a, the first brake fluid suction pump 102a is communicated with a brake fluid suction hose, the other end of the brake fluid suction hose is communicated with a material inlet of a first brake fluid electromagnetic angle seat valve 104a, and a signal input end of the first brake fluid electromagnetic angle seat valve 104a is connected with a signal output end of a first brake fluid storage valve of the controller. The material outlet of the first brake fluid electromagnetic angle seat valve 104a is communicated with the material inlet of a first brake fluid infusion pump 106a, the material outlet of the first brake fluid infusion pump 106a is communicated with the material inlet of a brake fluid feeding end valve 108 through a brake fluid infusion tube, a brake fluid pressure detector 107 is arranged on the brake fluid infusion tube, the signal output end of the brake fluid pressure detector 107 is connected with the signal input end of the brake fluid pressure of a controller, and the material outlet of the brake fluid feeding end valve 108 is communicated with a brake fluid filling machine.

Preferably, the first brake fluid infusion pump 106a is a pneumatic diaphragm pump, the driving gas input end of the first brake fluid infusion pump 106a is connected to one end of the first brake fluid gas transmission branch pipe, the other end of the first brake fluid gas transmission branch pipe is communicated with the tail end of the brake fluid gas transmission main pipe, and the start end of the brake fluid gas transmission main pipe is connected to the compressed air pipe. And a brake fluid pneumatic triple piece 111, a brake fluid pump electromagnetic valve 110 and a brake fluid idle-run-out prevention protector 109 are sequentially arranged on the brake fluid gas transmission main pipe along the airflow direction.

When the brake fluid is required to be delivered, the controller sends a delivery start command to the brake fluid subsystem, and the controller sends a communication command to the first brake fluid solenoid angle seat valve 104a to communicate the first brake fluid reservoir 101a with the brake fluid delivery tube. The controller sends a communication instruction to the brake fluid pump solenoid valve 110, so that the brake fluid gas transmission main pipe is communicated with the compressed air pipe, the compression control in the compressed air pipe is transmitted to the first brake fluid infusion pump 106a through the brake fluid gas transmission main pipe and enters from the driving gas input end of the first brake fluid infusion pump 106a, the first brake fluid infusion pump 106a is opened through the air pressure of compressed air, the pressure is provided for the brake fluid through the first brake fluid infusion pump 106a, and the brake fluid in the first brake fluid storage tank 101a is pumped to the brake fluid filling port.

Preferably, the brake fluid subsystem further includes a second brake fluid reservoir 101b, a second brake fluid suction pump 102b is provided in the second brake fluid reservoir 101b, the second brake fluid suction pump 102b is also connected to a second brake fluid electromagnetic angle seat valve 104b through a brake fluid suction hose, and the second brake fluid electromagnetic angle seat valve 104b is connected to a start end of a brake fluid supply pipe. And the signal input end of the second brake fluid electromagnetic angle seat valve 104b is connected with the signal output end of a second brake fluid storage valve of the controller. And a brake fluid flow detector 105 is arranged on the brake fluid supply pipe, and the signal output end of the brake fluid flow detector 105 is connected with the brake fluid flow signal input end of the controller. Wherein the first brake fluid reservoir 101a and the second brake fluid reservoir 101b are installed for one use and one standby.

Preferably, the brake fluid subsystem further comprises a brake fluid barrel change audible and visual alarm, and the signal input end of the brake fluid barrel change audible and visual alarm is connected with the brake fluid alarm signal output end of the controller.

When the detection signal of the brake fluid flow detector 105 is smaller than the set value, the controller immediately closes the first brake fluid electromagnetic angle seat valve 104a, opens the second brake fluid electromagnetic angle seat valve 104b, sends an alarm instruction to the brake fluid barrel-changing audible and visual alarm and sends a brake fluid barrel-changing audible and visual alarm signal through the brake fluid barrel-changing audible and visual alarm; when the brake fluid flow detector 105 detects that the pipeline fluid is interrupted again, the second brake fluid electromagnetic angle seat valve 104b is immediately closed, the first brake fluid electromagnetic angle seat valve 104a is opened, an alarm instruction is sent to the brake fluid barrel replacement audible and visual alarm, and a brake fluid barrel replacement audible and visual alarm signal is sent through the brake fluid barrel replacement audible and visual alarm; and the process is circulated.

Preferably, the first brake fluid reservoir 101a and the second brake fluid reservoir 101b are provided with drying cylinders 103 at their respective air vents.

Preferably, the first brake fluid infusion pump 106a is further connected in parallel with a second brake fluid infusion pump 106b, and the first brake fluid infusion pump 106a and the second brake fluid infusion pump 106b are installed one by one for one use and one by one for standby, preferably, a material inlet, a material outlet and a driving gas input end of the first brake fluid infusion pump 106a are all provided with a manual valve, a material inlet, a material outlet and a driving gas input end of the second brake fluid infusion pump 106b are also all provided with a manual valve, when the first brake fluid infusion pump 106a fails, the material inlet, the material outlet and the driving gas input end of the first brake fluid infusion pump 106a are cut off by the manual valve, and the material inlet, the material outlet and the driving gas input end of the second brake fluid infusion pump 106b are connected, so as to realize switching of the first brake fluid infusion pump 106a and the second brake fluid infusion pump 106 b.

The second brake fluid infusion pump 106b is a pneumatic diaphragm pump, the driving gas input end of the second brake fluid infusion pump 106b is connected with one end of the second brake fluid gas transmission branch pipe, and the other end of the second brake fluid gas transmission branch pipe is communicated with the tail end of the brake fluid gas transmission main pipe.

The cooling liquid subsystem comprises a cooling liquid unloading unit and a cooling liquid station area conveying unit. The coolant dump unit is used to transfer the coolant in the coolant tanker to two coolant stainless steel storage tanks 305. The cooling liquid station area conveying unit is used for conveying cooling liquid in the two cooling liquid stainless steel storage tanks 305 to the cooling liquid filling machine.

The cooling liquid unloading unit comprises a cooling liquid conveying subunit and a cooling liquid gas recovery subunit. The coolant liquid delivery sub-unit is used to transfer the coolant liquid in the coolant tanker into two coolant stainless steel storage tanks 305. The coolant gas recovery sub-unit is used for conveying the coolant gas in the two coolant stainless steel storage tanks 305 to the coolant tank truck.

The cooling liquid conveying subunit comprises a cooling liquid unloading connector 301, a material inlet of the cooling liquid unloading connector 301 is communicated with a cooling liquid tank truck, a material outlet of the cooling liquid unloading connector 301 is communicated with a material inlet of a first cooling liquid electromagnetic angle seat valve 302, and a signal input end of the first cooling liquid electromagnetic angle seat valve 302 is connected with a cooling liquid unloading signal output end of the controller. A material outlet of a first cooling liquid electromagnetic angle seat valve 302 is communicated with a material inlet of a first cooling liquid unloading pump 304a through a cooling liquid station area conveying main pipe, a cooling liquid unloading flow detector 303 is arranged on the cooling liquid station area conveying main pipe, a signal output end of the cooling liquid unloading flow detector 303 is connected with a cooling liquid unloading signal input end of a controller, a material outlet of the first cooling liquid unloading pump 304a is communicated with two cooling liquid stainless steel storage tanks 305 through two cooling liquid station area conveying branch pipes, and cooling liquid level meters are arranged in the cooling liquid stainless steel storage tanks 305. The signal output end of the cooling liquid level meter is connected with the signal input end of the cooling liquid level of the controller, when the cooling liquid level meter detects that the cooling liquid in the cooling liquid stainless steel storage tank 305 is smaller than a set value, the controller drives the first cooling liquid electromagnetic angle seat valve 302 to be communicated, the controller sends a liquid unloading starting instruction to the cooling liquid unloading unit, the cooling liquid in the refrigerant tank truck is transferred into the two cooling liquid stainless steel storage tanks 305, and meanwhile, the controller sends a conveying stopping instruction to the cooling liquid station area conveying unit. When the coolant liquid level meter detects that the coolant in the coolant stainless steel storage tanks 305 is smaller than a set value, the controller drives the first coolant electromagnetic angle seat valve 302 to block, sends a stop liquid unloading instruction to the coolant liquid unloading unit, stops transferring the coolant in the coolant tank truck to the two coolant stainless steel storage tanks 305, and simultaneously sends a start conveying instruction to the coolant station area conveying unit. Preferably, the ends of the coolant station area delivery manifolds extend into the bottom of the coolant stainless steel reservoir 305.

Preferably, the first coolant pump 304a is an air-operated diaphragm pump, the driving air input end of the first coolant pump 304a is connected to one end of the first coolant liquid-unloading air-conveying branch pipe, the other end of the first coolant liquid-unloading air-conveying branch pipe is communicated with the tail end of the coolant liquid-unloading air-conveying main pipe, and the start end of the coolant liquid-unloading air-conveying main pipe is connected to the compressed air pipe. And a cooling liquid discharging pneumatic triple piece 306, a cooling liquid discharging pump electromagnetic valve 307 and a cooling liquid discharging idle-run protector 308 are sequentially arranged on the cooling liquid discharging gas transmission main pipe along the airflow direction. And the signal input end of the electromagnetic valve of the cooling liquid unloading pump 307 is connected with the driving signal output end of the cooling liquid station pump of the controller.

When the coolant needs to be unloaded, the controller sends a delivery stop instruction to the coolant station area delivery unit, meanwhile, the controller sends a discharge start instruction to the coolant station area delivery unit, the controller sends a communication instruction to the coolant unloading pump electromagnetic valve 307, the coolant unloading gas delivery main pipe is communicated with the compressed air pipe, the compressed control in the compressed air pipe is delivered to the first coolant unloading pump 304a through the coolant unloading gas delivery main pipe and enters from the driving gas input end of the first coolant unloading pump 304a, the first coolant unloading pump 304a is opened through the air pressure of compressed air, the first coolant unloading pump 304a provides pressure for the coolant through the first coolant unloading pump 304a, and the coolant is pumped into the two coolant stainless steel storage tanks 305.

Preferably, the first coolant pump 304a is connected in parallel with a second coolant pump 304b, and preferably, the second coolant pump 304b is also an air-operated diaphragm pump, the driving air input end of the second coolant pump 304b is connected to one end of the second coolant liquid-discharging air-conveying branch pipe, and the other end of the second coolant liquid-discharging air-conveying branch pipe is communicated with the end of the coolant liquid-discharging air-conveying main pipe.

And the first cooling liquid unloading pump 304a and the second cooling liquid unloading pump 304b are installed one by one, the material inlet, the material outlet and the driving air input end of the first cooling liquid unloading pump 304a are all provided with manual valves, the material inlet, the material outlet and the driving air input end of the second cooling liquid unloading pump 304b are also all provided with manual valves, when the first cooling liquid unloading pump 304a fails, the material inlet, the material outlet and the driving air input end of the first cooling liquid unloading pump 304a are cut off by the manual valves, and the material inlet, the material outlet and the driving air input end of the second cooling liquid unloading pump 304b are connected, so that the first cooling liquid unloading pump 304a and the second cooling liquid unloading pump 304b are switched.

The coolant gas recovery subunit comprises two coolant gas recovery pipes communicated with the tops of the coolant stainless steel storage tanks 305, the other ends of the coolant gas recovery pipes are communicated with a material inlet of a second coolant electromagnetic angle seat 316 valve, and a signal input end of the second coolant electromagnetic angle seat 316 valve is connected with a coolant recovery signal output end of the controller. The material outlet of the second cooling liquid electromagnetic angle seat 316 valve is connected with a cooling liquid gas recovery joint 315 and is communicated with a cooling liquid gas inlet of the cooling liquid tank truck through the cooling liquid gas recovery joint 315. The cooling liquid gas recovery subunit is used for recovering the cooling liquid which is volatilized to form a gas state into the cooling liquid tank truck for recovery, so that the loss of the cooling liquid is reduced, and meanwhile, the gas formed by the cooling liquid is prevented from leaking in the air, and the environmental pollution is avoided.

Coolant liquid station district conveying unit includes that the top communicates two the coolant liquid transfer line of coolant liquid stainless steel storage tank 305 bottom transfusion mouth, the terminal first coolant liquid transfer pump 309a material import of intercommunication of coolant liquid transfer line, first coolant liquid transfer pump 309a material export passes through coolant liquid station district conveyer pipe intercommunication third coolant liquid electromagnetism angle seat valve 311 material import, third coolant liquid electromagnetism angle seat valve 311 material export intercommunication coolant liquid filling machine, third coolant liquid electromagnetism angle seat valve 311 signal input part connection director coolant liquid filling signal output part. And a cooling liquid station area conveying pressure detector 310 is arranged on the cooling liquid station area conveying pipe, the signal output end of the cooling liquid station area conveying pressure detector 310 is connected with the cooling liquid station area conveying pressure signal input end of the controller, and the pipe pressure conveyed by the cooling liquid station area is monitored in real time through the cooling liquid station area conveying pressure detector 310.

Preferably, the first coolant liquid transfer pump 309a is a pneumatic diaphragm pump, the driving gas input end of the first coolant liquid transfer pump 309a is connected to one end of the first coolant station area gas transmission branch pipe, the other end of the first coolant station area gas transmission branch pipe is communicated with the tail end of the coolant station area gas transmission main pipe, and the start end of the coolant station area gas transmission main pipe is connected to the compressed air pipe. And a cooling liquid pneumatic triple piece 312, a cooling liquid infusion pump electromagnetic valve 313 and a cooling liquid idle-run protector 314 are sequentially arranged on the cooling liquid station area gas transmission main pipe along the airflow direction. And the signal input end of the electromagnetic valve 313 of the cooling liquid infusion pump is connected with the driving signal output end of the cooling liquid station area pump of the controller.

When the cooling liquid station area transportation is needed, the controller sends a transportation stop instruction to the cooling liquid standby transportation unit, the controller sends a transportation start instruction to the cooling liquid station area transportation unit, the controller sends a communication instruction to the cooling liquid infusion pump electromagnetic valve 313, the cooling liquid station area gas main pipe is communicated with the compressed air pipe, the compression control in the compressed air pipe is transported to the first cooling liquid infusion pump 309a through the cooling liquid station area gas main pipe and enters from the driving gas input end of the first cooling liquid infusion pump 309a, the first cooling liquid infusion pump 309a is opened through the air pressure of compressed air, pressure is provided for the cooling liquid through the first cooling liquid infusion pump 309a, and the cooling liquid in the two cooling liquid stainless steel storage tanks 305 is pumped to the cooling liquid filling port.

Preferably, the first cooling liquid infusion pump 309a is connected in parallel with a second cooling liquid infusion pump 309b, and preferably, the second cooling liquid infusion pump 309b is also a pneumatic diaphragm pump, the driving air input end of the second cooling liquid infusion pump 309b is connected to one end of a second cooling liquid air delivery branch pipe, and the other end of the second cooling liquid air delivery branch pipe is communicated with the tail end of the cooling liquid air delivery main pipe.

And the first cooling liquid infusion pump 309a and the second cooling liquid infusion pump 309b are installed one by one, the material inlet, the material outlet and the driving gas input end of the first cooling liquid infusion pump 309a are all provided with manual valves, the material inlet, the material outlet and the driving gas input end of the second cooling liquid infusion pump 309b are also all provided with manual valves, when the first cooling liquid infusion pump 309a fails, the material inlet, the material outlet and the driving gas input end of the first cooling liquid infusion pump 309a are cut off through the manual valves, and the material inlet, the material outlet and the driving gas input end of the second cooling liquid infusion pump 309b are connected, so that the first cooling liquid infusion pump 309a and the second cooling liquid infusion pump 309b are switched.

The cooling liquid subsystem further comprises a cooling liquid standby conveying unit, and the cooling liquid standby conveying unit is used for continuously conveying cooling liquid to the cooling liquid filling machine when the cooling liquid station conveying unit cannot work.

The reserve conveying unit of coolant liquid includes the reserve liquid storage pot 401a of first coolant liquid, be equipped with first coolant liquid imbibition pump 402a in the reserve liquid storage pot 401a of first coolant liquid, first coolant liquid imbibition pump 402a intercommunication coolant liquid imbibition hose, the coolant liquid imbibition hose other end intercommunication fourth coolant liquid electromagnetism angle seat valve 403a material import, the reserve liquid storage valve signal output part of fourth coolant liquid electromagnetism angle seat valve 403a signal input part connection controller first coolant liquid, the reserve liquid storage of coolant liquid branch pipe intercommunication coolant liquid is responsible for the head end in the material export of fourth coolant liquid electromagnetism angle seat valve 403a, the reserve liquid storage of coolant liquid is responsible for terminal intercommunication first coolant liquid reserve transfer pump 405a material entry, the reserve transfer pump 405a material export of first coolant liquid communicates third coolant liquid electromagnetism angle seat valve 311 material entry.

Preferably, the first cooling liquid backup infusion pump 405a is a pneumatic diaphragm pump, the driving air input end of the first cooling liquid backup infusion pump 405a is connected with one end of the first cooling liquid backup air delivery branch pipe, the other end of the first cooling liquid backup air delivery branch pipe is communicated with the tail end of the cooling liquid backup air delivery main pipe, and the start end of the cooling liquid backup air delivery main pipe is connected with the compressed air pipe. And a cooling liquid standby pneumatic triple piece 409, a cooling liquid standby infusion pump electromagnetic valve 408 and a cooling liquid standby idle driving prevention protector 407 are sequentially arranged on the cooling liquid standby gas transmission main pipe along the airflow direction. The signal input end of the electromagnetic valve 408 of the cooling liquid standby infusion pump is connected with the driving signal output end of the cooling liquid standby infusion pump of the controller.

When the standby cooling liquid transportation is needed, the controller sends a transportation stop instruction to the cooling liquid station area transportation unit, sends a transportation start instruction to the cooling liquid standby transportation unit, and sends a communication instruction to the fourth cooling liquid electromagnetic angle seat valve 403a to communicate the first standby cooling liquid storage tank 401a with the main cooling liquid standby storage pipe. The controller sends the intercommunication instruction to coolant liquid reserve infusion pump solenoid valve 408, let the reserve gas transmission main pipe of coolant liquid communicate with the compressed air pipe, let the compression control in the compressed air pipe carry to first coolant liquid reserve infusion pump 405a department through the reserve gas transmission main pipe of coolant liquid, and get into from the drive gas input of first coolant liquid reserve infusion pump 405a, open first coolant liquid reserve infusion pump 405a through compressed air's atmospheric pressure, provide pressure for the coolant liquid through first coolant liquid reserve infusion pump 405a, pump the coolant liquid in the reserve liquid storage pot 401a of first coolant liquid to coolant liquid filling opening department.

Preferably, the first cooling liquid backup infusion pump 405a is connected in parallel with a second cooling liquid backup infusion pump 405b, and preferably, the second cooling liquid backup infusion pump 405b is also a pneumatic diaphragm pump, a driving gas input end of the second cooling liquid backup infusion pump 405b is connected with one end of a second cooling liquid backup gas transmission branch pipe, and the other end of the second cooling liquid backup gas transmission branch pipe is communicated with the tail end of a cooling liquid backup gas transmission main pipe.

And first cooling liquid reserve infusion pump 405a and second cooling liquid reserve infusion pump 405b are installed with one by one, the material import, the material export and the drive gas input of first cooling liquid reserve infusion pump 405a all are equipped with the hand valve, the material import, the material export and the drive gas input of second cooling liquid reserve infusion pump 405b also all are equipped with the hand valve, when first cooling liquid reserve infusion pump 405a trouble, cut off the material import, the material export and the drive gas input of first cooling liquid reserve infusion pump 405a through the hand valve to and put through the material import, the material export and the drive gas input of second cooling liquid reserve infusion pump 405b, realize first cooling liquid reserve infusion pump 405a and the switching of second cooling liquid reserve infusion pump 405b with this.

Preferably, the cooling liquid standby delivery unit is further equipped with a second cooling liquid standby storage tank 401b, a second cooling liquid suction pump 402b is arranged in the second cooling liquid standby storage tank 401b, the second cooling liquid suction pump 402b is also communicated with a fifth cooling liquid electromagnetic angle seat valve 403b through a cooling liquid suction hose, and the fifth cooling liquid electromagnetic angle seat valve 403b is communicated with a second cooling liquid standby storage branch pipe and is communicated with the starting end of a cooling liquid standby storage main pipe. The standby liquid storage main pipe of the cooling liquid is provided with a standby cooling liquid conveying flow detector 404, and the signal output end of the standby cooling liquid flow detector 404 is connected with the standby cooling liquid flow signal input end of the controller. The first coolant reserve tank 401a and the second coolant reserve tank 401b are installed for one use and one reserve.

Preferably, the cooling liquid standby conveying unit further comprises a cooling liquid standby conveying and barrel replacing audible and visual alarm, and a signal input end of the cooling liquid standby conveying and barrel replacing audible and visual alarm is connected with a cooling liquid standby conveying alarm signal output end of the controller.

When the detection signal of the cooling liquid standby flow detector 404 is smaller than the set value, the controller immediately closes the fourth cooling liquid electromagnetic angle seat valve 403a, opens the fifth cooling liquid electromagnetic angle seat valve 403b, and sends an alarm instruction to the cooling liquid standby conveying barrel-changing audible and visual alarm, and sends a cooling liquid barrel-changing audible and visual alarm signal through the cooling liquid standby conveying barrel-changing audible and visual alarm; when the standby cooling liquid flow detector 404 detects that the pipeline fluid is interrupted again, the controller immediately closes the fifth cooling liquid electromagnetic angle seat valve 403b, opens the fourth cooling liquid electromagnetic angle seat valve 403a, sends an alarm instruction to the cooling liquid standby conveying barrel-changing audible and visual alarm, and sends a cooling liquid barrel-changing audible and visual alarm signal through the cooling liquid standby conveying barrel-changing audible and visual alarm; and the process is circulated.

The refrigerant subsystem comprises a first refrigerant steel bottle 201a, a first steel bottle scale 211a is arranged at the bottom of the first refrigerant steel bottle 201a, the signal output end of the first steel bottle scale 211a is connected with the weight signal input end of a first steel bottle of the controller, the first refrigerant steel bottle 201a is communicated with one end of a first refrigerant liquid supply branch pipe, a first refrigerant electromagnetic angle seat valve 202a is arranged on the first refrigerant liquid supply branch pipe, and the signal input end of the first refrigerant electromagnetic angle seat valve 202a is connected with the signal output end of a first refrigerant valve of the controller. The other end of the first refrigerant liquid supply branch pipe is connected with one end of a refrigerant liquid supply main pipe, the other end of the refrigerant liquid supply main pipe is communicated with a material inlet of a first plunger pump 205a, a material outlet of the first plunger pump 205a is communicated with a material inlet of a third refrigerant electromagnetic angle seat valve 207 through a refrigerant conveying main pipe, a second refrigerant pressure sensor 206 is arranged on the refrigerant conveying main pipe, a signal output end of the second refrigerant pressure sensor 206 is connected with a pressure sensing signal input end at the refrigerant tail end of a controller, and the third refrigerant electromagnetic angle seat valve 207 is communicated with an inlet of a refrigerant filling machine. The other end of the refrigerant liquid supply main pipe is communicated with a material inlet of a refrigerant overpressure drainage valve 204, and a material outlet of the refrigerant overpressure drainage valve 204 is communicated with a material inlet of a refrigerant conveying main pipe.

Preferably, the first plunger pump 205a is a pneumatic plunger pump, the driving air input end of the first plunger pump 205a is connected to one end of the first refrigerant air transmission branch pipe, the other end of the first refrigerant air transmission branch pipe is communicated with the tail end of the refrigerant air transmission main pipe, and the start end of the refrigerant air transmission main pipe is connected to the compressed air pipe. The refrigerant pneumatic triplet 210, the refrigerant electromagnetic valve 209 and the refrigerant idle-strike prevention protector 208 are sequentially arranged on the refrigerant gas transmission main pipe along the airflow direction.

When the refrigerant is required to be conveyed, the controller sends a conveying starting instruction to the refrigerant subsystem, and the controller sends a communication instruction to the first refrigerant electromagnetic angle seat valve 202a, so that the first refrigerant steel cylinder 201a is communicated with the refrigerant liquid supply main pipe. The controller sends a communication instruction to the refrigerant solenoid valve 209, so that the coolant station area gas transmission main pipe is communicated with the compressed air pipe, the compression control in the compressed air pipe is transmitted to the first plunger pump 205a through the coolant station area gas transmission main pipe and enters from the driving gas input end of the first plunger pump 205a, the first plunger pump 205a is opened through the air pressure of the compressed air, the pressure is provided for the coolant through the first plunger pump 205a, and the refrigerant in the first refrigerant steel cylinder 201a is pumped to the refrigerant filling port.

The refrigerant subsystem comprises a second refrigerant steel bottle 201b, a second steel bottle scale 211b is arranged at the bottom of the second refrigerant steel bottle 201b, the signal output end of the second steel bottle scale 211b is connected with the weight signal input end of the second steel bottle of the controller, the second refrigerant steel bottle 201b is communicated with one end of a second refrigerant liquid supply branch pipe, a second refrigerant electromagnetic angle seat valve 202b is arranged on the second refrigerant liquid supply branch pipe, and the signal input end of the second refrigerant electromagnetic angle seat valve 202b is connected with the signal output end of the second refrigerant steel bottle 201b of the controller. The other end of the second refrigerant liquid supply branch pipe is also connected with one end of the refrigerant liquid supply main pipe. The first refrigerant cylinder 201a and the second refrigerant cylinder 201b are provided at once.

Preferably, the refrigerant subsystem further comprises a refrigerant barrel-changing audible and visual alarm, and the signal input end of the refrigerant barrel-changing audible and visual alarm is connected with the refrigerant alarm signal output end of the controller.

When the detection signal of the first steel cylinder scale 211a is smaller than a set value, the controller immediately closes the first refrigerant electromagnetic angle seat valve, opens the second refrigerant electromagnetic angle seat valve, sends an alarm instruction to the refrigerant barrel-changing audible and visual alarm and sends a refrigerant barrel-changing audible and visual alarm signal through the refrigerant barrel-changing audible and visual alarm; when the detection signal of the first steel cylinder scale 211b is smaller than a set value, the controller immediately closes the second refrigerant electromagnetic angle seat valve, opens the first refrigerant electromagnetic angle seat valve, sends an alarm instruction to the refrigerant barrel-changing audible and visual alarm and sends a refrigerant barrel-changing audible and visual alarm signal through the refrigerant barrel-changing audible and visual alarm; and the process is circulated.

Preferably, a first refrigerant pressure sensor 203 is arranged on the refrigerant liquid supply main pipe, and the signal output end of the first refrigerant pressure sensor 203 is connected with the pressure signal input end of the refrigerant starting end of the controller. When the first refrigerant pressure sensor 203 detects low pressure and does not recover within a set time, for example, 3 minutes, the controller sends an alarm instruction to the refrigerant barrel-changing audible and visual alarm, and sends a refrigerant barrel-changing audible and visual alarm signal through the refrigerant barrel-changing audible and visual alarm to remind of tank changing. The first refrigerant pressure sensor 203, the first steel cylinder 201a and the second steel cylinder 201b are backup schemes for each other, providing double insurance.

Preferably, the first plunger pump 205a is further connected in parallel with a second plunger pump 205b, and a signal input end of the second plunger pump 205b is connected to a signal output end of a second refrigerant pump of the controller, wherein the second plunger pump 205b is a pneumatic plunger pump, a driving gas input end of the second plunger pump 205b is connected to one end of a second refrigerant gas transmission branch pipe, and the other end of the second refrigerant gas transmission branch pipe is communicated with the tail end of the refrigerant gas transmission main pipe. And the first plunger pump 205a and the second plunger pump 205b are installed one by one, the material inlet, the material outlet and the driving gas input end of the first plunger pump 205a are all provided with manual valves, the material inlet, the material outlet and the driving gas input end of the second plunger pump 205b are also all provided with manual valves, when the first plunger pump 205a fails, the material inlet, the material outlet and the driving gas input end of the first plunger pump 205a are cut off through the manual valves, and the material inlet, the material outlet and the driving gas input end of the second plunger pump 205b are connected, so that the first plunger pump 205a and the second plunger pump 205b are switched.

Preferably, the centralized liquid supply system of the automobile assembly workshop further comprises a windshield cleaning liquid subsystem. The air window cleaning liquid subsystem comprises a methanol liquid discharging unit, a liquid mixing unit, a mixed liquid station conveying unit and a mixed liquid standby conveying unit, wherein a methanol liquid discharging output end of the controller is connected with an input end of the methanol liquid discharging unit, a mixed liquid output end of the controller is connected with an input end of the mixed liquid unit, a mixed liquid station conveying output end of the controller is connected with an input end of the mixed liquid station conveying unit, and a mixed liquid standby conveying output end of the controller is connected with an input end of the mixed liquid standby conveying unit.

The methanol liquid discharging unit comprises a methanol liquid conveying subunit and a methanol gas recovery subunit. The methanol liquid station conveying unit comprises a methanol liquid discharging connector 501, a material inlet of the methanol liquid discharging connector 501 is communicated with a material outlet of a methanol tank truck, the material outlet of the methanol liquid discharging connector 501 is communicated with a material inlet of a first methanol electromagnetic angle seat valve 502, and a signal input end of the first methanol electromagnetic angle seat valve 502 is connected with a methanol liquid discharging signal output end of a controller. A material outlet of the first methanol electromagnetic angle seat valve 502 is communicated with a material inlet of a first methanol liquid unloading pump 504a through a methanol conveying main pipe, a methanol flow detector 503 is arranged on the methanol conveying main pipe, a signal output end of the methanol flow detector 503 is connected with a methanol liquid unloading signal input end of a controller, the material outlet of the first methanol liquid unloading pump 504a is communicated with two methanol stainless steel storage tanks 505 through two methanol conveying branch pipes, and the two methanol stainless steel storage tanks 505 are internally provided with liquid unloading ultrasonic level meters and liquid unloading leakage detectors. When the liquid-discharging ultrasonic liquid level meter detects that the methanol in the methanol stainless steel storage tank 505 is smaller than a set value, the controller drives the first methanol electromagnetic angle seat valve 502 to be opened, and meanwhile, the controller sends a liquid-discharging starting instruction to the methanol liquid-discharging unit to transfer the methanol in the methanol tank truck into the methanol stainless steel storage tank 505. When the liquid-discharging ultrasonic liquid level meter detects that the methanol in the methanol stainless steel storage tank 505 is larger than a set value, the controller drives the first methanol electromagnetic angle seat valve 502 to be closed, and meanwhile, the controller sends a liquid-discharging stopping instruction to the methanol liquid-discharging unit to stop transferring the methanol in the methanol tank truck into the methanol stainless steel storage tank 505. When the liquid unloading leakage detector detects that the liquid unloading in the methanol stainless steel storage tank 505 has leakage, the controller drives the first methanol electromagnetic angle seat valve 502 to be closed, and meanwhile, the controller sends a liquid unloading stopping instruction to the methanol liquid unloading unit.

Preferably, the end of the methanol delivery manifold extends into the bottom of the methanol stainless steel tank 505 to avoid splashing liquid and accelerate the evaporation of methanol liquid. Preferably, the material outlets of the two methanol stainless steel storage tanks 505 are communicated with a nitrogen protection system, the nitrogen protection system comprises a nitrogen bottle 511, the gas outlet of the nitrogen bottle 511 is communicated with one end of a nitrogen pipe, the other end of the nitrogen pipe is communicated with the material outlets of the two methanol stainless steel storage tanks 505, and the nitrogen pipe is provided with a manual valve.

Preferably, the first methanol liquid unloading pump 504a is a pneumatic diaphragm pump, the driving gas input end of the first methanol liquid unloading pump 504a is connected to one end of the first methanol gas transmission branch pipe, the other end of the first methanol gas transmission branch pipe is communicated with the tail end of the methanol gas transmission main pipe, and the start end of the methanol gas transmission main pipe is connected to the compressed air pipe. The methanol gas transmission main pipe is sequentially provided with a methanol pneumatic triple piece 508, a methanol liquid discharge pump electromagnetic valve 509 and a methanol idle driving prevention protector 510 along the gas flow direction. The signal input end of the methanol liquid unloading pump electromagnetic valve 509 is connected with the driving signal output end of the methanol station area pump of the controller. Preferably, the first methanol unloading pump 504a is connected in parallel with a second methanol unloading pump, and the first methanol unloading pump 504a and the second methanol unloading pump are installed one by one, the material inlet, the material outlet and the driving gas input end of the first methanol unloading pump 504a are all provided with a manual valve, the material inlet, the material outlet and the driving gas input end of the second methanol unloading pump 504b are also all provided with a manual valve, when the first methanol unloading pump 504a fails, the material inlet, the material outlet and the driving gas input end of the first methanol unloading pump 504a are cut off by the manual valves, and the material inlet, the material outlet and the driving gas input end of the second methanol unloading pump 504b are connected, so as to realize the switching of the first methanol unloading pump 504a and the second methanol unloading pump 504 b.

Preferably, the second methanol liquid unloading pump 504b is also a pneumatic diaphragm pump, the driving gas input end of the second methanol liquid unloading pump 504b is connected with one end of the second methanol gas transmission branch pipe, and the other end of the second methanol gas transmission branch pipe is communicated with the tail end of the methanol gas transmission main pipe.

The methanol gas recovery subunit comprises two methanol gas recovery pipes communicated with the tops of the methanol stainless steel storage tanks, the other ends of the methanol gas recovery pipes are communicated with a material inlet of a second methanol electromagnetic angle seat valve 506, and a signal input end of the second methanol electromagnetic angle seat valve 506 is connected with a methanol recovery signal output end of the controller. And a material outlet of the second methanol electromagnetic angle seat valve 506 is connected with a methanol gas recovery joint 507 and is communicated with a gas inlet of a methanol tank truck through the methanol gas recovery joint 507. The methanol gas recovery subunit is used for recovering the methanol volatilized to form a gas state into the methanol tank truck for recovery, so that the loss of the methanol is reduced, and meanwhile, the gas formed by the methanol is prevented from leaking in the air, and the environmental pollution is avoided.

Mix the liquid unit and include high liquid level case 602 and mixing box 603, high liquid level case 602 is located the top of mixing box 603, high liquid level case 602 includes two and holds the case, holds case 602a and water for methyl alcohol respectively and holds case 602b, the methyl alcohol of high liquid level case 602 holds case 602a and water and holds case 602b and all communicate with mixing box 603 through shifting the pipe, it all is equipped with the transfer solenoid valve on the pipe to shift, shift solenoid valve signal input part connection director mixing signal output, be equipped with agitator 603a in the mixing box 603.

A methanol ultrasonic liquid level instrument 611 and a methanol magnetostrictive liquid level sensor 612 are arranged in the methanol containing box 602a, the detection signal output end of the methanol ultrasonic liquid level instrument 611 is connected with the first methanol liquid level signal input end of the controller, and the methanol magnetostrictive liquid level sensor 612 is connected with the second methanol liquid level signal input end of the controller.

A water ultrasonic level meter 613 and a water magnetostrictive liquid level sensor 614 are arranged in the water containing tank 602b, the detection signal output end of the water ultrasonic level meter 613 is connected with the first water level signal input end of the controller, and the water magnetostrictive liquid level sensor 614 is connected with the second water level signal input end of the controller. Simultaneously, the methanol ultrasonic liquid level instrument 611 and the methanol magnetostrictive liquid level sensor 612 are arranged to prevent methanol from overflowing the high-level liquid tank due to a certain failure, so that the precision and the reliability are both ensured.

The bottom of methyl alcohol containing box 602a communicates mixed methanol pump 601 material export, mixed methanol pump 601 material import communicates with two methyl alcohol stainless steel storage tanks 505 through two mixing branch pipes, and two the mixing branch pipe all stretches to the bottom of methyl alcohol stainless steel storage tank 505. Water holds case 602b intercommunication mixed water pump 606 material export, mixed water pump 606 material import intercommunication water tank, be equipped with the mixed water level gauge in the water holds case 602b, mixed water level gauge signal output part connection director mixed water liquid level signal input.

Preferably, the mixed methanol pump 601 is a pneumatic diaphragm pump, the driving gas input end of the mixed methanol pump 601 is connected with one end of a mixed methanol gas transmission branch pipe, the other end of the mixed methanol gas transmission branch pipe is communicated with the tail end of a mixed gas transmission main pipe, and the initial end of the mixed gas transmission main pipe is connected with a compressed air pipe. And a mixed methanol infusion pump electromagnetic valve 608 and a mixed methanol idle-pumping prevention protector 607 are sequentially arranged on the mixed methanol gas transmission branch pipe along the gas flow direction. The signal input end of the electromagnetic valve 608 of the mixed methanol infusion pump is connected with the driving signal output end of the mixed methanol pump 601 of the controller. And a mixed pneumatic triple piece 609 is arranged on the mixed gas transmission main pipe. When any one of the methanol ultrasonic level meter 611 or the methanol magnetostrictive level sensor 612 detects that the methanol in the methanol containing tank 602a is larger than a set value, the controller sends a disconnection instruction to the electromagnetic valve 608 of the mixed methanol infusion pump, and disconnects the driving gas of the mixed methanol pump 601, so as to stop the mixed methanol pump 601 from continuing to deliver the methanol.

Preferably, the mixed water pump 606 is a pneumatic diaphragm pump, the driving gas input end of the mixed water pump 606 is connected with one end of the mixed water gas transmission branch pipe, and the other end of the mixed water gas transmission branch pipe is communicated with the tail end of the mixed gas transmission main pipe. And a mixed water infusion pump electromagnetic valve 610 and a mixed water idle driving prevention protector 615 are sequentially arranged on the mixed water gas delivery branch pipe along the airflow direction. The signal input end of the mixed water infusion pump solenoid valve 610 is connected with the driving signal output end of the controller mixed water pump 606. When any one of the water ultrasonic level meter 613 and the water magnetostrictive level sensor 614 detects that the water in the water containing tank 602b is greater than a set value, the controller sends a disconnection command to the mixed water infusion pump solenoid valve 610 to disconnect the driving gas of the mixed water pump 606, thereby stopping the mixed water pump 606 from continuing to deliver water.

The bottom of the mixing box 603 is provided with a methanol mixed liquid outlet which is communicated with a material inlet of a third methanol electromagnetic angle seat valve 604a, the material outlet of the third methanol electromagnetic angle seat valve 604a is communicated with the material inlet of a mixed liquid storage tank 604 through a mixed liquid gravity flow pipe, and the signal input end of the third methanol electromagnetic angle seat valve 604a is connected with the signal output end of a mixed liquid end transfer valve of a controller. And the mixed liquid gravity flow pipe extends into the bottom of the mixed liquid storage tank 604, and a mixed liquid ultrasonic level meter and a mixed liquid leakage detector are also arranged in the mixed liquid storage tank 604. The signal output end of the mixed liquid ultrasonic level meter is connected with the first mixed liquid level signal input end of the controller, and the signal output end of the mixed liquid leakage detector is connected with the mixed liquid leakage detection signal input end of the controller. When the mixed liquid ultrasonic level meter detects that the mixed liquid in the mixed liquid storage tank 604 is smaller than a set value, the controller drives the third methanol electromagnetic angle seat valve 604a to be opened, the mixed liquid in the mixing box 603 is transferred into the mixed liquid storage tank 604, and meanwhile, the controller sends a conveying stopping instruction to the mixed liquid station conveying unit. When the mixed liquor ultrasonic level meter detects that the mixed liquor in the mixed liquor storage tank 604 exceeds a set value, the controller drives the third methanol electromagnetic angle seat valve 604a to close, stops transferring the mixed liquor in the mixing tank 603 into the mixed liquor storage tank 604, and simultaneously sends a conveying starting instruction to the mixed liquor station conveying unit. When the mixed liquid leakage detector detects that the mixed liquid in the mixed liquid storage tank 604 leaks, the controller drives the third methanol electromagnetic angle seat valve 604a to be closed, and meanwhile, the controller sends a conveying stopping instruction to the mixed liquid station conveying unit.

The mixed liquor standby delivery unit includes a first mixed liquor station area delivery pump 701 a. The material inlet of the first mixed liquid station area delivery pump 701a is communicated with the material outlet of the mixed liquid storage tank 604 through the mixed liquid station area delivery pipe, the mixed liquid station area delivery pipe extends into the bottom of the mixed liquid storage tank 604, the material outlet of the first mixed liquid station area delivery pump 701a is communicated with one end of a mixed liquid remote supply pipe, the mixed liquid remote supply pipe is sequentially provided with a methanol concentration online detector 703 and a mixed liquid pressure detector 704 along the liquid supply direction, the other end of the mixed liquid remote supply pipe is communicated with the material inlet of a fourth methanol mixed liquid electromagnetic angle seat valve 708, and the material outlet of the fourth methanol mixed liquid electromagnetic angle seat valve 708 is communicated with a methanol mixed liquid filling machine. The signal input end of the fourth alcohol mixed liquid electromagnetic angle seat valve 708 is connected with the controller mixed liquid conveying on-off end.

The material outlet of the mixed liquid storage tank 604 is communicated with the material inlet of the methanol gas overpressure drainage valve 702 through a methanol gas conveying pipe, and the material outlet of the methanol gas overpressure drainage valve 702 is communicated with the mixed liquid remote liquid supply pipe.

Preferably, the first mixed liquid station area delivery pump 701a is a pneumatic diaphragm pump, the driving air input end of the first mixed liquid station area delivery pump 701a is connected with one end of the first mixed liquid air delivery branch pipe, the other end of the first mixed liquid air delivery branch pipe is communicated with the tail end of the mixed liquid air delivery main pipe, and the starting end of the mixed liquid air delivery main pipe is connected with the compressed air pipe. And a mixed liquid pneumatic triple 707, a mixed liquid infusion pump electromagnetic valve 706 and a mixed liquid idle driving prevention protector 705 are sequentially arranged on the mixed liquid gas transmission main pipe along the airflow direction. The signal input end of the mixed liquid infusion pump electromagnetic valve 706 is connected with the driving signal output end of the mixed liquid pump of the controller.

Preferably, the first mixed liquor station area feed pump 701a is connected in parallel with a second mixed liquor station area feed pump 701b, and the first mixed liquor station area delivery pump 701a and the second mixed liquor station area delivery pump 701b are installed one by one, the material inlet, the material outlet and the driving gas input end of the first mixed liquid station area delivery pump 701a are all provided with manual valves, the material inlet, the material outlet and the driving gas input end of the second mixed liquid station area delivery pump 701b are also provided with manual valves, when the first mixed liquor station area delivery pump 701a fails, the material inlet, the material outlet and the driving gas input of the first mixed liquor station area delivery pump 701a are cut off by a manual valve, and the material inlet, the material outlet and the driving gas input end of the second mixed liquid station area delivery pump 701b are communicated, this switches the first mixed liquid station area feed pump 701a and the second mixed liquid station area feed pump 701 b.

Preferably, the second mixed liquid station area delivery pump 701b is also a pneumatic diaphragm pump, the driving gas input end of the second mixed liquid station area delivery pump 701b is connected with one end of the second mixed liquid gas transmission branch pipe, and the other end of the second mixed liquid gas transmission branch pipe is communicated with the tail end of the mixed liquid gas transmission main pipe.

The standby mixed liquid conveying unit comprises a first mixed liquid storage tank 801a, a first mixed liquid imbibition pump 802a is arranged in the first mixed liquid storage tank 801a, the first mixed liquid imbibition pump 802a is communicated with a mixed liquid imbibition hose, the other end of the mixed liquid imbibition hose is communicated with a material inlet of a fifth mixed liquid electromagnetic angle seat valve 803a, a signal input end of the fifth mixed liquid electromagnetic angle seat valve 803a is connected with a signal output end of a first mixed liquid standby liquid storage valve of a controller, a material outlet of the fifth mixed liquid electromagnetic angle seat valve 803a is communicated with a material inlet of a first mixed liquid standby liquid infusion pump 804a, and a material outlet of the first mixed liquid standby infusion pump 804a is communicated with a material inlet of a fourth methanol mixed liquid electromagnetic angle seat valve.

Preferably, the first mixed liquid standby infusion pump 804a is a pneumatic diaphragm pump, the driving air input end of the first mixed liquid standby infusion pump 804a is connected to one end of the first mixed liquid standby air delivery branch pipe, the other end of the first mixed liquid standby air delivery branch pipe is communicated with the tail end of the mixed liquid standby air delivery main pipe, and the starting end of the mixed liquid standby air delivery main pipe is connected to the compressed air pipe. A mixed liquid standby pneumatic triple 808, a mixed liquid standby infusion pump electromagnetic valve 807 and a mixed liquid standby idle-pumping prevention protector 806 are sequentially arranged on the mixed liquid standby air transmission main pipe along the airflow direction. The signal input end of the mixed liquid standby infusion pump electromagnetic valve 807 is connected with the driving signal output end of the mixed liquid standby infusion pump of the controller.

Preferably, the first mixed solution backup infusion pump 804a is connected in parallel with the second mixed solution backup infusion pump 804b, and the first mixed liquid backup infusion pump 804a and the second mixed liquid backup infusion pump 804b are installed one by one, the material inlet, the material outlet and the driving gas input end of the first mixed liquid standby infusion pump 804a are all provided with manual valves, the material inlet, the material outlet and the driving gas input end of the second mixed liquid standby infusion pump 804b are also provided with manual valves, when the first mixed liquid standby infusion pump 804a is in failure, the material inlet, the material outlet and the driving gas input end of the first mixed liquid standby infusion pump 804a are cut off by the manual valve, and the material inlet, the material outlet and the driving gas input end of the second mixed liquid standby infusion pump 804b are connected, this realizes switching between the first mixed-liquid-backup infusion pump 804a and the second mixed-liquid-backup infusion pump 804 b.

Preferably, the second mixed liquid standby infusion pump 804b is also a pneumatic diaphragm pump, a driving gas input end of the second mixed liquid standby infusion pump 804b is connected with one end of the second mixed liquid standby gas transmission branch pipe, and the other end of the second mixed liquid standby gas transmission branch pipe is communicated with the tail end of the mixed liquid standby gas transmission main pipe.

Preferably, the mixed solution standby conveying unit is further provided with a second mixed solution storage tank 801b, a second mixed solution suction pump 802a is arranged in the second mixed solution storage tank 801b, the second mixed solution suction pump 802a is also communicated with a sixth mixed solution electromagnetic angle seat valve 803b through a mixed solution suction hose, and the sixth mixed solution electromagnetic angle seat valve 803b is communicated with the starting end of the mixed solution supply pipe. The signal input end of the sixth mixed liquid electromagnetic angle seat valve 803b is connected with the signal output end of the standby liquid storage valve of the second mixed liquid of the controller. And a mixed liquid flow detector 809 is arranged on the mixed liquid supply pipe, and the signal output end of the mixed liquid flow detector 809 is connected with the mixed liquid flow signal input end of the controller. The first mixed liquid tank 801a and the second mixed liquid tank 801b are installed for one use and one standby.

Preferably, the mixed liquid standby conveying unit further comprises a mixed liquid standby conveying and barrel changing audible and visual alarm, and the signal input end of the mixed liquid standby conveying and barrel changing audible and visual alarm is connected with the signal output end of the mixed liquid standby conveying and alarm of the controller.

When the detection signal of the mixed liquid flow detector 809 is less than the set value, the controller immediately closes the fifth mixed liquid electromagnetic angle seat valve 803a, opens the sixth mixed liquid electromagnetic angle seat valve 803b, and sends an alarm instruction to the mixed liquid standby conveying barrel-changing audible and visual alarm, and sends a mixed liquid barrel-changing audible and visual alarm signal through the mixed liquid standby conveying barrel-changing audible and visual alarm; when the mixed liquid flow detector 809 detects that the pipeline fluid is interrupted again, the controller immediately closes the sixth mixed liquid electromagnetic angle seat valve 803b, opens the fifth mixed liquid electromagnetic angle seat valve 803a, and sends an alarm instruction to the mixed liquid standby conveying barrel-changing audible and visual alarm, and sends a mixed liquid barrel-changing audible and visual alarm signal through the mixed liquid standby conveying barrel-changing audible and visual alarm; and the process is circulated.

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.

Claims (10)

1. The utility model provides a liquid supply system is concentrated in car assembly workshop which characterized in that: the brake fluid control system comprises a controller, a brake fluid subsystem, a cooling fluid subsystem and a refrigerant subsystem, wherein the brake fluid control output end of the controller is connected with the control input end of the brake fluid subsystem, the cooling fluid control output end of the controller is connected with the control input end of the cooling fluid subsystem, and the refrigerant control output end of the controller is connected with the control input end of the refrigerant subsystem.

2. The centralized liquid supply system of the automobile assembly plant as recited in claim 1, wherein: the brake fluid subsystem comprises a first brake fluid storage tank (101a), a first brake fluid suction pump (102a) is arranged in the first brake fluid storage tank (101a), the first brake fluid suction pump (102a) is communicated with a brake fluid suction hose, the other end of the brake fluid suction hose is communicated with a material inlet of a first brake fluid electromagnetic angle seat valve (104a), and the signal input end of the first brake fluid electromagnetic angle seat valve (104a) is connected with the signal output end of a first brake fluid storage valve of the controller; a material outlet of the first brake fluid electromagnetic angle seat valve (104a) is communicated with a material inlet of a first brake fluid infusion pump (106a), a material outlet of the first brake fluid infusion pump (106a) is communicated with a material inlet of a brake fluid supply end valve (108) through a brake fluid infusion tube, a brake fluid pressure detector (107) is arranged on the brake fluid infusion tube, a signal output end of the brake fluid pressure detector (107) is connected with a brake fluid pressure signal input end of a controller, and a material outlet of the brake fluid supply end valve (108) is communicated with a brake fluid filling machine;

the first brake fluid infusion pump (106a) is a pneumatic diaphragm pump, the driving gas input end of the first brake fluid infusion pump (106a) is connected with one end of a first brake fluid gas transmission branch pipe, the other end of the first brake fluid gas transmission branch pipe is communicated with the tail end of a brake fluid gas transmission main pipe, and the starting end of the brake fluid gas transmission main pipe is connected with a compressed air pipe; and a brake fluid pneumatic triple piece (111), a brake fluid pump electromagnetic valve (110) and a brake fluid idle-driving prevention protector (109) are sequentially arranged on the brake fluid gas transmission main pipe along the airflow direction.

3. The centralized liquid supply system of the automobile assembly plant as recited in claim 2, wherein: the brake fluid subsystem is also provided with a second brake fluid storage tank (101b), a second brake fluid suction pump (102b) is arranged in the second brake fluid storage tank (101b), the second brake fluid suction pump (102b) is also communicated with a second brake fluid electromagnetic angle seat valve (104b) through a brake fluid suction hose, and the second brake fluid electromagnetic angle seat valve (104b) is communicated with the starting end of a brake fluid supply pipe; the signal input end of a second brake fluid electromagnetic angle seat valve (104b) is connected with the signal output end of a second brake fluid storage valve of the controller; a brake fluid flow detector (105) is arranged on the brake fluid supply pipe, and the signal output end of the brake fluid flow detector (105) is connected with the brake fluid flow signal input end of the controller; wherein the first brake fluid storage tank (101a) and the second brake fluid storage tank (101b) are installed for one use and one standby;

the brake fluid subsystem further comprises a brake fluid barrel changing audible and visual alarm, and the signal input end of the brake fluid barrel changing audible and visual alarm is connected with the brake fluid alarm signal output end of the controller.

4. The method of claim 3, wherein: and drying cylinders (103) are arranged on the air vents of the first brake fluid storage tank (101a) and the second brake fluid storage tank (101 b).

5. The centralized liquid supply system of the automobile assembly plant as recited in claim 1, wherein: the cooling liquid subsystem comprises a cooling liquid unloading unit and a cooling liquid station area conveying unit;

the cooling liquid unloading unit comprises a cooling liquid conveying subunit and a cooling liquid gas recovery subunit;

the cooling liquid conveying subunit comprises a cooling liquid unloading connector (301), a material inlet of the cooling liquid unloading connector (301) is communicated with a cooling liquid tank car, a material outlet of the cooling liquid unloading connector (301) is communicated with a material inlet of a first cooling liquid electromagnetic angle seat valve (302), and a signal input end of the first cooling liquid electromagnetic angle seat valve (302) is connected with a cooling liquid unloading signal output end of the controller; a material outlet of a first cooling liquid electromagnetic angle seat valve (302) is communicated with a material inlet of a first cooling liquid unloading pump (304a) through a cooling liquid station area conveying main pipe, a cooling liquid unloading flow detector (303) is arranged on the cooling liquid station area conveying main pipe, a signal output end of the cooling liquid unloading flow detector (303) is connected with a cooling liquid unloading signal input end of a controller, the material outlet of the first cooling liquid unloading pump (304a) is communicated with two cooling liquid stainless steel storage tanks (305) through two cooling liquid station area conveying branch pipes, cooling liquid level meters are arranged in the two cooling liquid stainless steel storage tanks (305), and signal output ends of the cooling liquid level meters are connected with a cooling liquid level signal input end of the controller;

the first cooling liquid unloading pump (304a) is a pneumatic diaphragm pump, the driving air input end of the first cooling liquid unloading pump (304a) is connected with one end of a first cooling liquid unloading air conveying branch pipe, the other end of the first cooling liquid unloading air conveying branch pipe is communicated with the tail end of a cooling liquid unloading air conveying main pipe, and the starting end of the cooling liquid unloading air conveying main pipe is connected with a compressed air pipe; a cooling liquid discharging pneumatic triple piece (306), a cooling liquid discharging pump electromagnetic valve (307) and a cooling liquid discharging idle-run-proof protector (308) are sequentially arranged on the cooling liquid discharging gas transmission main pipe along the airflow direction; and the signal input end of an electromagnetic valve of the cooling liquid unloading pump (307) is connected with the driving signal output end of a cooling liquid station pump of the controller.

6. The centralized liquid supply system of the automobile assembly plant as recited in claim 5, wherein: the cooling liquid and gas recovery sub-unit comprises cooling liquid and gas recovery pipes communicated with the tops of the two cooling liquid stainless steel storage tanks (305), the other ends of the cooling liquid and gas recovery pipes are communicated with a material inlet of a second cooling liquid electromagnetic angle seat (316), and a valve signal input end of the second cooling liquid electromagnetic angle seat (316) is connected with a cooling liquid recovery signal output end of the controller; and a material outlet of the second cooling liquid electromagnetic angle seat (316) valve is connected with a cooling liquid gas recovery joint (315) and is communicated with a cooling liquid gas inlet of the cooling liquid tank truck through the cooling liquid gas recovery joint (315).

7. The centralized liquid supply system of the automobile assembly plant as recited in claim 5, wherein: the cooling liquid station area conveying unit comprises a cooling liquid conveying pipe, the initial end of the cooling liquid conveying pipe is communicated with two liquid conveying ports at the bottom of the cooling liquid stainless steel storage tank (305), the tail end of the cooling liquid conveying pipe is communicated with a material inlet of a first cooling liquid conveying pump (309a), a material outlet of the first cooling liquid conveying pump (309a) is communicated with a material inlet of a third cooling liquid electromagnetic angle seat valve (311) through the cooling liquid station area conveying pipe, a material outlet of the third cooling liquid electromagnetic angle seat valve (311) is communicated with a cooling liquid filling machine, and a signal input end of the third cooling liquid electromagnetic angle seat valve (311) is connected with a cooling liquid filling signal output end of a controller; a cooling liquid station area conveying pressure detector (310) is arranged on the cooling liquid station area conveying pipe, the signal output end of the cooling liquid station area conveying pressure detector (310) is connected with the cooling liquid station area conveying pressure signal input end of the controller, and pipe pressure conveyed by the cooling liquid station area is monitored in real time through the cooling liquid station area conveying pressure detector (310);

the first cooling liquid infusion pump (309a) is a pneumatic diaphragm pump, the driving gas input end of the first cooling liquid infusion pump (309a) is connected with one end of a gas transmission branch pipe of the first cooling liquid station area, the other end of the gas transmission branch pipe of the first cooling liquid station area is communicated with the tail end of a gas transmission main pipe of the cooling liquid station area, and the starting end of the gas transmission main pipe of the cooling liquid station area is connected with a compressed air pipe; a cooling liquid pneumatic triple piece (312), a cooling liquid infusion pump electromagnetic valve (313) and a cooling liquid idle driving prevention protector (314) are sequentially arranged on the cooling liquid station area gas transmission main pipe along the airflow direction; and the signal input end of a cooling liquid infusion pump electromagnetic valve (313) is connected with the driving signal output end of a cooling liquid station pump of the controller.

8. The centralized liquid supply system of the automobile assembly plant as recited in claim 5, wherein: the cooling liquid subsystem further comprises a cooling liquid standby conveying unit, the cooling liquid standby conveying unit comprises a first cooling liquid standby liquid storage tank (401a), a first cooling liquid suction pump (402a) is arranged in the first cooling liquid standby liquid storage tank (401a), the first cooling liquid suction pump (402a) is communicated with a cooling liquid suction hose, the other end of the cooling liquid suction hose is communicated with a material inlet of a fourth cooling liquid electromagnetic angle seat valve (403a), a signal input end of the fourth cooling liquid electromagnetic angle seat valve (403a) is connected with a signal output end of a first cooling liquid standby liquid storage valve of the controller, a material outlet of the fourth cooling liquid electromagnetic angle seat valve (403a) is communicated with a starting end of the cooling liquid standby liquid storage main pipe through a first cooling liquid standby liquid storage branch pipe, the tail end of the cooling liquid standby liquid storage main pipe is communicated with a material inlet of the first cooling liquid standby liquid infusion pump (405a), and a material outlet of the first cooling liquid standby infusion pump (405a) is communicated with a material inlet of the third cooling liquid electromagnetic angle seat valve (;

the first cooling liquid standby infusion pump (405a) is a pneumatic diaphragm pump, the driving air input end of the first cooling liquid standby infusion pump (405a) is connected with one end of the first cooling liquid standby air delivery branch pipe, the other end of the first cooling liquid standby air delivery branch pipe is communicated with the tail end of the cooling liquid standby air delivery main pipe, and the starting end of the cooling liquid standby air delivery main pipe is connected with a compressed air pipe; a cooling liquid standby pneumatic triple piece (409), a cooling liquid standby infusion pump electromagnetic valve (408) and a cooling liquid standby idle driving prevention protector (407) are sequentially arranged on the cooling liquid standby gas transmission main pipe along the airflow direction; the signal input end of the electromagnetic valve (408) of the cooling liquid standby infusion pump is connected with the driving signal output end of the cooling liquid standby infusion pump of the controller.

9. The centralized liquid supply system of the automobile assembly plant as recited in claim 1, wherein: the refrigerant subsystem comprises a first refrigerant steel bottle (201a), a first steel bottle scale (211a) is arranged at the bottom of the first refrigerant steel bottle (201a), the signal output end of the first steel bottle scale (211a) is connected with the weight signal input end of a first steel bottle of the controller, the first refrigerant steel bottle (201a) is communicated with one end of a first refrigerant liquid supply branch pipe, a first refrigerant electromagnetic angle seat valve (202a) is arranged on the first refrigerant liquid supply branch pipe, and the signal input end of the first refrigerant electromagnetic angle seat valve (202a) is connected with the signal output end of a first refrigerant valve of the controller; the other end of the first refrigerant liquid supply branch pipe is connected with one end of a refrigerant liquid supply main pipe, the other end of the refrigerant liquid supply main pipe is communicated with a material inlet of a first plunger pump (205a), a material outlet of the first plunger pump (205a) is communicated with a material inlet of a third refrigerant electromagnetic angle seat valve (207) through a refrigerant conveying main pipe, a second refrigerant pressure sensor (206) is arranged on the refrigerant conveying main pipe, a signal output end of the second refrigerant pressure sensor (206) is connected with a pressure sensing signal input end at the refrigerant tail end of a controller, and the third refrigerant electromagnetic angle seat valve (207) is communicated with an inlet of a refrigerant filling machine; the other end of the refrigerant liquid supply main pipe is communicated with a material inlet of a refrigerant overpressure drainage valve (204), and a material outlet of the refrigerant overpressure drainage valve (204) is communicated with a material inlet end of the refrigerant conveying main pipe;

the first plunger pump (205a) is a pneumatic plunger pump, the driving gas input end of the first plunger pump (205a) is connected with one end of a first refrigerant gas transmission branch pipe, the other end of the first refrigerant gas transmission branch pipe is communicated with the tail end of a refrigerant gas transmission main pipe, and the starting end of the refrigerant gas transmission main pipe is connected with a compressed air pipe; the refrigerant gas transmission main pipe is sequentially provided with a refrigerant pneumatic triple piece (210), a refrigerant electromagnetic valve (209) and a refrigerant air-blast-proof protector (208) along the airflow direction.

10. The centralized liquid supply system of the automobile assembly plant as recited in claim 9, wherein: the refrigerant subsystem comprises a second refrigerant steel cylinder (201b), a second steel cylinder scale (211b) is arranged at the bottom of the second refrigerant steel cylinder (201b), the signal output end of the second steel cylinder scale (211b) is connected with the weight signal input end of a second steel cylinder of the controller, the second refrigerant steel cylinder (201b) is communicated with one end of a second refrigerant liquid supply branch pipe, a second refrigerant electromagnetic angle seat valve (202b) is arranged on the second refrigerant liquid supply branch pipe, and the signal input end of the second refrigerant electromagnetic angle seat valve (202b) is connected with the valve signal output end of the second refrigerant steel cylinder (201b) of the controller; the other end of the second refrigerant liquid supply branch pipe is also connected with one end of the refrigerant liquid supply main pipe; the first refrigerant steel cylinder (201a) and the second refrigerant steel cylinder (201b) are arranged one by one;

the refrigerant subsystem further comprises a refrigerant barrel-changing audible and visual alarm, and the signal input end of the refrigerant barrel-changing audible and visual alarm is connected with the refrigerant alarm signal output end of the controller.

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