CN106064325B - Electrolyzed water, oil and gas three-phase energy-saving minimal lubrication cooling system - Google Patents

Abstract

The invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication and cooling system, which is characterized in that it comprises: an electrolyzed water generator, at least one micro-spray device, at least one oil-water-gas spray device; the water inlet of the electrolyzed water generator The end is connected to the water source, and the alkaline water outlet is connected to the oil-water-air injection device through a hose; the compressed air is divided into two routes, one of which is directly connected to the oil-water-air injection device; The oil outlet of the minimum quantity lubrication device is connected with the oil-water-air injection device. The advantage is that it solves the problems of large amount of lubricant used in the traditional technology, serious environmental pollution, uneven mixing of water and oil in the prior art, poor liquid discharge effect and frequent addition of water to increase labor intensity.

Description

Electrolyzed water, oil and gas three-phase energy-saving minimal lubrication cooling system

technical field

The invention relates to a lubricating system, in particular to a water supply device for an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

Background technique

In the field of traditional machining, metal processing usually involves cutting, drilling, tapping and other processing processes that easily cause the workpiece to heat up rapidly. This type of processing requires frictional contact between workpieces, and timely lubrication should usually be carried out.

At present, lubricating oils such as coolants, emulsions or cutting oils are mostly used for lubrication and cooling of existing metal cold processing. These types of lubricating oils are sprayed on the processing parts in large quantities during metal processing, usually in the form of uninterrupted showering. , In this way, the same cooling and lubrication are carried out in other parts that do not need cooling and lubrication, resulting in a large amount of cooling medium, causing waste, and polluting the environment.

In order to solve the above problems, the research on the micro-quantity lubrication technology has made great progress in recent years. However, the micro-quantity lubrication technology uses compressed air as the cooling medium and cleans up the processing debris. During the installation, the compressed air provided by the air compressor is often insufficient, and the power consumption increases. In addition, when the two phases of water and oil are mixed and input, problems such as uneven separation and mixing of water and oil will occur, resulting in poor liquid discharge effect. When used in a micro-quantity lubrication device, good lubrication and cooling effects cannot be achieved. In order to solve these problems, the technicians of our company designed the publication number: CN103722447A, and the patent name is: oil-water-air three-phase energy-saving micro-lubrication system. This patented technology has the following problems in the actual application process: 1. Due to the inconvenient addition of anti-rust agent, the user does not add anti-rust agent, resulting in easy rusting of the workpiece; 2. It is inconvenient to add water, and water can only be added after stopping the machine and releasing the pressure ; Multiple devices cannot supply water together; 3. The water pressure is unstable and is greatly affected by the pressure in the water container.

Contents of the invention

The present invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system to overcome the above-mentioned defects in the prior art and improve efficiency.

The present invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication and cooling system, comprising an electrolyzed water generator, at least one micro-spray device, and at least one oil-water-gas spray device; the water inlet end of the electrolyzed water generator is externally connected to a water source, The alkaline water outlet is connected to the oil-water-air injection device through a hose; the compressed air is divided into two paths, one of which is directly connected to the oil-water-air injection device; The oil outlet is connected with the oil-water-air injection device.

The present invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system, which also has the following features: the electrolyzed water generator includes: an electrolyzer, a diaphragm, an anode electrode and a cathode electrode; the diaphragm divides the electrolyzer into two cavities; The anode electrode and the cathode electrode are placed in the two chambers respectively to form the anode chamber and the cathode chamber; the purified water enters the anode electrolyzer and the cathode electrolyzer respectively; after the water in the cathode electrolyzer is electrolyzed, the water is supplied to the oil-gas three-phase energy-saving micro-lubrication cooling system use.

The present invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication and cooling system, which also has the following characteristics: it also includes a filter assembly; water is first filtered through the filter assembly to produce clean water; Alkaline electrolyzed water is used in electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

The invention provides an electrolyzed water oil-gas three-phase energy-saving micro-lubrication cooling system, which also has the following characteristics: the electrolyzed water generator also includes: a cathode chamber water inlet, a cathode chamber water outlet, an anode chamber water inlet, an anode chamber water outlet, an electrolytic Water outlet and wastewater outlet; clean water enters the cathode chamber from the water inlet of the cathode chamber, flows from the cathode chamber outlet to the electrolyzed water outlet; clean water enters the anode chamber from the anode chamber water inlet, and flows from the anode chamber outlet to the waste water Outlet;

Preferably, the water inlet of the anode chamber has a branch joint to adjust the amount of water entering the anode chamber.

Preferably, the branch joint is a three-way structure, which are respectively the water port of the branch joint, the outlet of the utilization water and the outlet of the recovery water.

The water outlet is directly connected with the water inlet of the anode chamber.

There is a flow regulating plug on one side of the recovery water outlet.

Preferably, the recycled water outlet is connected to the waste water outlet.

The present invention provides an electrolytic water oil-gas three-phase energy-saving micro-lubrication cooling system, which also has the following characteristics: it also includes a water inlet, a combined water tank, a diaphragm pump and a water outlet; the combined water tank has a water purification tank and an electrolytic water storage tank; After the water enters from the water inlet, after being filtered by the filter assembly, it enters the water inlet of the anode chamber, the water inlet of the cathode chamber and the water purification storage tank; the electrolyzed water flowing out of the electrolysis water outlet enters the electrolysis water storage tank; The water in the water storage tank passes through the diaphragm pump and flows out from the water outlet.

Preferably, a recovery box is also included; the water flowing out of the waste water outlet flows into the recovery box; excess clean water filtered by the filter assembly also enters the recovery box.

Preferably, the filter assembly includes a granular activated carbon filter and a nanofiltration/microfiltration membrane filter; the clean water enters from the water inlet, first passes through the granular activated carbon filter, and then is filtered through the nanofiltration/microfiltration membrane filter.

The invention provides an electrolyzed water, oil and gas three-phase energy-saving micro-lubrication and cooling system, which also has the following characteristics: the water inlet valve of the cathode chamber is arranged on the pipeline where the filter assembly enters the water inlet of the cathode chamber; the water inlet valve of the anode chamber is arranged on the filter On the pipeline from the component to the water inlet of the anode chamber; the water inlet valve of the clean water tank is set on the pipeline from the filter component to the clean water storage tank; the recovery valve is set on the pipeline from the filter component to the recovery tank; the clean water outlet valve is set on the The clean water storage tank is on the pipeline to the diaphragm pump; the electrolyzed water outlet valve is arranged on the pipeline from the electrolytic water storage tank to the diaphragm pump.

The invention provides an electrolyzed water oil-gas three-phase energy-saving micro-lubrication and cooling system, which also has the following characteristics: the electrolyzed water water storage tank has an electrolyzed water level switch; when the electrolyzed water level switch is triggered, the water inlet valve of the anode chamber and the cathode chamber The water inlet valve is connected, and the recovery valve and the water inlet valve of the clean water tank are closed.

Preferably, there is a clean water level switch in the clean water storage tank; when the clean water level switch is triggered, the anode chamber water inlet valve and the cathode chamber water inlet valve are closed, and the recovery valve and the clean water tank water inlet valve are connected.

The invention provides an electrolytic water oil-gas three-phase energy-saving micro-lubrication cooling system, which also has the following characteristics: it also includes a control panel; the control panel has a water purification switch and an electrolysis water switch; when the water purification switch is turned on, the water purification outlet valve is turned on , the electrolyzed water outlet valve is closed; when the electrolyzed water switch is turned on, the electrolyzed water outlet valve is connected, and the purified water outlet valve is closed.

Preferably, it also includes an alarm light for water shortage in purified water. When the water level switch of the purified water is triggered, the alarm light for water shortage in purified water is turned on.

Preferably, it also includes a water shortage alarm light for the electrolytic water, and when the clean water level switch is triggered, the water shortage alarm light for the electrolytic water is turned on.

Further, the present invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication and cooling system, which may also have the following features: the micro-spray oil-gas device includes: an oil cup, a precision pneumatic pump, at least one frequency controller and an air source; a precision pneumatic An oil cup is set on the pump, and the frequency controller controls the oil output frequency of the precision pneumatic pump; compressed air passes through the air source, passes through the frequency controller, and then enters the precision pneumatic pump; each precision pneumatic pump is equipped with an oil-water-air injection device.

Further, the present invention provides an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system, which may also have the following features: the oil-water-gas injection device includes an oil-water-gas mixing control device and an energy-saving nozzle.

As a preference, the oil-water-air mixing control device includes a regulating water valve and an oil-water-gas three-way module; water enters the oil-water-gas three-way module through the regulating water valve, and the regulating water valve controls the size of the water flow; the precision pneumatic pump pumps the oil from the oil cup Out, together with the compressed air, enter the oil-water-air tee module.

As preferably, the energy-saving nozzle includes a nozzle body, a nested ring, a tee post, a sealing ring, and a water-oil mixing output pipe; the oil-water mixture is ejected from the water-oil mixing output pipe, and the gas enters the nozzle body and passes through the nesting ring from The water-oil mixed output pipe sprays out from the outside.

Beneficial Effects of the Invention

The invention provides an electrolytic water-oil-gas three-phase energy-saving micro-lubrication and cooling system to solve the problem of large amount of lubricant used in the traditional technology, serious environmental pollution, uneven mixing of water and oil in the prior art, poor liquid output and frequent increase in water addition The problem of labor intensity. The alkaline electrolyzed water generated by the electrolyzed water device effectively solves the problem of rust prevention

Description of drawings

Figure 1 is a schematic diagram of an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

Fig. 2 is a schematic structural diagram of an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

Fig. 3 is a connection diagram of the internal devices of the electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

Fig. 4 is a left side view of the electrolyzed alkaline water/purified water supply device.

Fig. 5 is a schematic diagram of the A-A sectional structure of the electrolyzed alkaline water/purified water supply device.

Fig. 6 is a right side view of the electrolyzed alkaline water/purified water supply device.

Fig. 7 is a schematic diagram of the cross-sectional structure of the electrolyzed water generator.

Fig. 8 is a schematic diagram of a cross-sectional structure of a shunt joint.

Fig. 9 is a circuit system control diagram.

Fig. 10 is a perspective view of the oil-water-air mixing control device.

Fig. 11 is a structural schematic diagram of an energy-saving nozzle.

reference sign

Water supply device-1 Micro oil injection device-2 Oil-water-air injection device-3

Body-10 Handle-101 Cooling hole-102

Roller-103 Exhaust fan-104 Power cord hole-105

Pipeline interface-11 Water inlet-110 Water outlet-111

Drain port-112 Granular activated carbon filter-12 Nanofiltration/microfiltration membrane filter-13

Recovery box-14 Electrolyzed water generator-15

Split fitting-151 Split fitting inlet-1511 Recovery water outlet-1512

Utilize water outlet-1513 flow adjustment plug-1514 water inlet-152

Waste water outlet-153 Electrolytic alkaline water outlet-154 Electrolyzer-155

Cathode electrode-1551 Ion-permeable membrane-1552 Anode electrode-1553

Anode chamber water outlet-1554 Cathode chamber water outlet-1555 Electrolyzer cover-1556

Electrolyzer body-1557 Rib-156 Shell cover-157

Outer shell-158 Combined water tank-16 Diaphragm pump-17

Solenoid valve-18 Recovery valve-181 Anode chamber inlet valve-182

Cathode chamber water inlet valve-183 Clean water tank water inlet valve-184 Electrolyzed water outlet valve-185

Clean water outlet valve-186 Control panel-19 Working indicator light-191

Water shortage alarm light for purified water-192 Water shortage alarm light for electrolytic water-193 Power switch-194

Water purification switch-195 Electrolyzed water switch-196 Oil cup-21

Precision pneumatic pump-22 Frequency regulator-23 Air source-24

Oil-water-gas mixing control device-31 Oil-water-gas tee module-312 Regulating water valve-311

Energy-saving nozzle-32 Nozzle body-321 Nesting ring-322

Tee column-323 Sealing ring-324 Inlet pipe-325

Oil inlet pipe-326 Water-oil mixed output pipe-327

Detailed ways

The present invention will be further described below in conjunction with the accompanying drawings and specific embodiments.

Figure 1 is a schematic diagram of an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

As shown in Figure 1, the electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system includes: an electrolyzed water generator, a micro-spray device 2, and an oil-water-gas spray device 3. The water inlet end of the electrolyzed water generating device is externally connected to a water source, and the alkaline water outlet end is connected to the oil-water-air injection device 2 through a hose; the compressed air is divided into two paths, one path is directly connected to the oil-water-air injection apparatus 3; the other path is used as The power is connected with the micro-quantity oil injection device 2 , and the oil outlet of the micro-quantity lubrication device 2 is connected with the oil-water-air injection device 3 .

Fig. 2 is a schematic structural diagram of an electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

As shown in FIG. 2 , the electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system in this embodiment is illustrated by taking the structure of one electrolyzed alkaline water/purified water supply device 1 and three micro-spray oil-gas devices 2 as an example. In practical applications, the number of micro-injection devices 2 can be set according to needs.

The electrolyzed water oil-gas three-phase energy-saving micro-lubrication cooling system includes: three micro-spray oil-gas devices 2, one electrolyzed alkaline water/clean water supply device 1, and oil-water-gas spray device 3. The oil-water-gas spraying device 3 is connected to the micro-spraying oil-gas device 2 through a hose; the electrolyzed alkaline water/purified water supply device 1 is connected to the oil-water-gas spraying device 2 through a hose respectively. The electrolyzed alkaline water/clean water supply device 1 supplies water to a plurality of oil-water-gas injection devices 3 at the same time.

Fig. 3 is a connection diagram of the internal devices of the electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system.

As shown in FIG. 3 , the water outlet 111 of the electrolyzed alkaline water/purified water supply device 1 is connected to the oil-water-gas injection device 3 . The micro fuel injection device 2 is connected with the oil water gas injection device 3 .

The micro-spraying device 2 includes: an oil cup 21 , a precision pneumatic pump 22 , a frequency controller 23 and an air source 24 . Multiple precision pneumatic pumps 22 can be provided as required.

An oil cup 21 is arranged on the precision pneumatic pump 22 , and a frequency controller 23 controls the oil output frequency of the precision pneumatic pump 22 .

The compressed air passes through the air source 24 , passes through the frequency controller 23 , and passes into the precision pneumatic pump 22 .

Each precision pneumatic pump 22 is equipped with an oil-water-air injection device 3 .

Fig. 4 is a left side view of the electrolyzed alkaline water/purified water supply device.

The control panel 19 of the electrolyzed alkaline water/purified water supply device 1 includes: a working indicator light 191, a pure water shortage alarm lamp 192, an electrolyzed water shortage alarm lamp 193, a power switch 194, a pure water switch 195, and an electrolyzed water switch 196. When the water purification switch is turned on, the water purification outlet valve is connected, and the electrolytic water outlet valve is closed; when the electrolysis water switch is turned on, the electrolysis water outlet valve is connected, and the water purification outlet valve is closed. When the purified water level switch is triggered, the purified water shortage alarm light turns on; when the purified water level switch is triggered, the electrolytic water shortage alarm light turns on.

Fig. 5 is a schematic cross-sectional structural view of the electrolyzed alkaline water/purified water supply device.

Fig. 6 is a right side view of the electrolyzed alkaline water/purified water supply device.

As shown in Figures 2 to 5, the electrolytic alkaline water/clean water supply device 1 includes: a control panel 19, a water inlet 110, a granular activated carbon filter 12, a nanofiltration/microfiltration membrane filter 13, an electrolytic water generator 15, Diaphragm pump 17, water outlet 111, recovery box 14, combined water tank 16, roller 103, handle 101, heat dissipation hole 102, water outlet 112, power line hole 105, exhaust fan 104.

The combined water tank 16 has a clean water storage tank and an electrolyzed water storage tank;

After the clean water enters from the water inlet, after filtering through the granular activated carbon filter 12 and the nanofiltration/microfiltration membrane filter 13, enter the clean water storage tank of the anode chamber water inlet, the cathode chamber water inlet and the combination water tank 16 respectively. The electrolyzed water flowing out of the electrolyzed water outlet enters the electrolyzed water storage tank. The water in the clean water storage tank and the electrolyzed water storage tank flows out from the water outlet 111 through the diaphragm pump 17 .

The water flowing out of the waste water outlet 153 flows into the recovery tank 14 ; the excess clean water filtered by the nanofiltration/microfiltration membrane filter 13 also enters the recovery tank 14 .

The water inlet valve 183 of the cathode chamber is arranged on the pipeline through which the filter assembly enters the water inlet of the cathode chamber. The anode chamber water inlet valve 182 is arranged on the pipeline from the filter assembly to the anode chamber water inlet. The clean water tank water inlet valve 184 filter assembly is on the pipeline to the clean water storage tank. The recovery valve 181 is arranged on the pipeline from the filter assembly to the recovery tank.

The clean water outlet valve 186 clean water storage tank is on the pipeline to the diaphragm pump. The electrolyzed water outlet valve 185 is on the pipeline from the electrolyzed water storage tank to the diaphragm pump.

Fig. 7 is a schematic diagram of the cross-sectional structure of the electrolyzed water generator.

Fig. 8 is a schematic diagram of a cross-sectional structure of a shunt joint.

As shown in Figures 7 and 8, the electrolyzed water generator 15 includes: a shunt joint 151, a shunt joint inlet 1511, a recycled water outlet 1512, a utilization water outlet 1513, a flow regulating plug 1514, a water inlet 152, a waste water outlet 153, an electrolytic Alkaline water outlet 154, electrolytic cell 155, cathode electrode 1551, ion-permeable diaphragm 1552, anode electrode 1553, anode chamber water outlet 1554, cathode chamber water outlet 1555, electrolytic cell cover 1556, electrolytic cell body 1557, ribs 156 , the shell cover 157, the shell body 158.

The diaphragm divides the electrolytic cell into two chambers; the two chambers respectively place the anode electrode and the cathode electrode to form the anode chamber and the cathode chamber; the purified water enters the anode electrolyzer and the cathode electrolyzer respectively; the water in the cathode electrolyzer is electrolyzed Finally, it is used in the water-oil-gas three-phase energy-saving minimal-quantity lubrication cooling system.

The clean water enters the cathode chamber from the water inlet of the cathode chamber, and flows from the water outlet of the cathode chamber to the electrolyzed water outlet. Clean water enters the anode chamber from the water inlet of the anode chamber, and flows from the water outlet of the anode chamber to the waste water outlet;

The shunt joint 151 and the water inlet 152 are fixed on the shell cover 157, the shell cover 157 is connected with the shell body 158 by connecting plate bolts, the rib plate 156 is connected with the shell cover 157 by bolts, and the electrolyzer 155 is fixed on the rib plate 156 by bolts. The cathode electrode 1551 and the anode electrode 1553 are respectively fixed on the electrolyzer cover 1556 by bolts. The utilization water outlet is directly connected to the water inlet of the anode chamber; the side of the recovery water outlet has a flow regulating plug; the recovery water outlet is connected to the waste water outlet.

The water flow P1 is divided into two parts by the branch joint 151 , and the flow of the two parts of the water flow can be adjusted by the flow regulating plug 1514 . Part of it enters the anode chamber on the left side of the electrolytic cell body 1557 through the water outlet 1513, and the other part flows to the waste water outlet 153 through the recycled water outlet 1512 for recycling. The water flow P2 flowing into the cathode chamber on the right is introduced through the water inlet 152 . The anode chamber and the cathode chamber are separated by an ion-permeable diaphragm 1552, and the ratio of water in the anode chamber to the cathode chamber is 3:1, which effectively improves the electrolysis efficiency. The obtained electrolyzed alkaline water is discharged through the cathode chamber water outlet 1555 through the electrolyzed alkaline water outlet 154 , and the electrolyzed waste water is recovered through the anode chamber water outlet 1554 through the waste water outlet 153 .

Fig. 9 is a circuit system control diagram.

3 to 9, when the electrolyzed water in the electrolyzed water storage tank in the combined water tank 16 is lower than the warning line, the limit switch is triggered, the electrolyzed water shortage alarm light 193 is on, and the anode chamber water inlet valve 182 and the cathode chamber are automatically connected at the same time The water inlet valve 183, the recovery valve 181 and the clean water tank water inlet valve 184 are in a closed state. Ordinary water enters the device through the water inlet 110 and then flows into the granular activated carbon filter 12, then flows into the nano-membrane filter 13, and after passing through the electrolyzed water generator 15, the electrolyzed water is transported to the electrolyzed water/purified water combined water tank 16. Assuming that 6 parts of water flow into the nano-membrane filter 13, they are divided into two equal parts, that is, 3 parts of pure water and 3 parts of water containing impurities, and 3 parts of pure water enter the electrolytic water generator 15 through the cathode chamber inlet valve 183 , 3 parts of water containing impurities enter the electrolytic water generator 15 through the anode chamber water inlet valve 182 . Since the ratio of the amount of water in the anode chamber to the cathode chamber is 3:1, only 1 part of water containing impurities is required to enter the anode chamber. At this time, the flow regulating plug 1514 in the shunt joint 151 can be adjusted to make the remaining 2 parts of water containing impurities enter the anode chamber. Water is recovered through recovery water outlet 1512 .

Turn on the electrolyzed water switch 196, turn on the electrolyzed water outlet valve 185, turn on the diaphragm pump 17, turn off the purified water outlet valve 186, and the electrolyzed water in the combined electrolyzed water/pure water tank 16 is driven by the diaphragm pump 17 to flow through the electrolyzed water The water outlet valve 185 , the diaphragm pump 17 , and the water outlet 111 are delivered to the oil-water-air injection device 3 .

Figure 10 is an axonometric view of the oil-water-gas mixing control device

As shown in FIG. 10 , the oil-water-gas mixing control device 31 is mainly composed of a regulating water valve 311 and an oil-water-gas three-way module 312 .

The water enters the oil-water-air three-way module 312 through the regulating water valve 311 of the oil-water-gas mixing control device 31 , and the regulating water valve 311 is used to control the size of the water flow. The precision pneumatic pump 22 of the micro-spraying device 2 pumps the oil out of the oil cup, and enters the oil-water-air tee module 312 together with the compressed air.

Fig. 11 is a structural schematic diagram of an energy-saving nozzle.

As shown in FIG. 11 , the energy-saving nozzle 32 includes a nozzle body 321 , a nesting ring 322 , a tee post 323 , a sealing ring 324 and a water-oil mixing output pipe 327 . The oil and water are mixed and sprayed out from the water-oil mixing output pipe 327 , the gas enters the nozzle body 321 and is sprayed out from the outside of the water-oil mixing output pipe 327 through the nesting ring 322 . Water, oil and gas are sprayed onto the workpiece and the tool at the same time.

Supply clean water status:

When the water level of the clean water storage tank in the combined water tank 16 is lower than the warning water level, the clean water level switch is triggered, the clean water shortage alarm light 192 is bright, and the recovery valve 181 and the clean water tank inlet valve 184 are automatically connected simultaneously, and the anode chamber The water inlet valve 182 and the cathode chamber water inlet valve 183 are in closed state.

Ordinary water flows into the granular activated carbon filter 12 after entering the device through the water inlet 110, and then flows into the nanofiltration membrane filter 13. After filtering, the pure water is delivered to the clean water storage tank of the combined water tank 16 through the clean water outlet valve 184.

Turn on the pure water switch 195, turn on the clean water outlet valve 186, turn on the diaphragm pump 17, turn off the electrolyzed water outlet valve 185, and the clean water in the combined water tank 16 is driven by the diaphragm pump 17, and flows through the clean water outlet valve 186, diaphragm The pump 17 and the water outlet 111 deliver to the oil-water-air injection device 3 .

Supply electrolyzed water status:

When the water level of the electrolyzed water storage tank in the combination water tank 16 is lower than the warning water level, the electrolyzed water level switch is triggered, the electrolyzed water water shortage alarm light 193 is on, and the automatic recovery valve 181 and the clean water tank inlet valve 184 are closed simultaneously, and the anode chamber enters Water valve 182 and cathode chamber water inlet valve 183 are connected.

Ordinary water enters the device through the water inlet 110 and then flows into the granular activated carbon filter 12, then flows into the nanofiltration membrane filter 13, and after filtration, the pure water is delivered to the anode chamber, the cathode chamber, and the anode chamber through the water inlet valve 182 and the cathode chamber water inlet valve 183 respectively. Electrolysis takes place in the cathode chamber. The electrolyzed water in the cathode chamber enters the clean water storage tank of the combined water tank 16 . The electrolyzed water and excess pure water in the anode chamber enter the recovery box.

Turn on the electrolyzed water switch 196, the electrolyzed water outlet valve 185 is connected, the diaphragm pump 17 is connected, the clean water outlet valve 186 is closed, the electrolyzed water in the combined water tank 16 is driven by the diaphragm pump 17, and flows through the net electrolyzed water outlet valve 185, The diaphragm pump 17 and the water outlet 111 deliver to the oil-water-air injection device 3 .

Claims (9)

1. An electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system, characterized in that: comprising: an electrolyzed water generator, at least one micro-spray device, at least one oil-water-gas spray device; the water inlet of the electrolyzed water generator The water source is externally connected, and the alkaline water outlet is connected to the oil-water-air injection device through a hose; the compressed air is divided into two paths, one path is directly connected to the oil-water-air injection device; The oil outlet of the micro-injection device is connected with the oil-water-air injection device; The electrolyzed water generator includes: an electrolytic cell, a diaphragm, an anode electrode and a cathode electrode; The diaphragm divides the electrolytic cell into two cavities; The two cavities respectively place the anode electrode and the cathode electrode to form an anode chamber and a cathode chamber; After the water enters the electrolytic cell and undergoes electrolysis, the alkaline electrolyzed water from the water outlet of the cathode chamber is used for the water-oil-gas three-phase energy-saving micro-lubrication cooling system; The membrane is an ion-permeable membrane; The ratio of the amount of water in the anode chamber to the cathode chamber is 3:1; It also includes a filter assembly; the water is first filtered through the filter assembly to produce clean water; the alkaline electrolyzed water produced by the clean water and electrolyzed water generator is used for the water-lyzed oil-gas three-phase energy-saving micro-lubrication cooling system; The filter assembly includes a granular activated carbon filter and a nanofiltration/microfiltration membrane filter; clean water enters from the water inlet, first passes through the granular activated carbon filter, and then is filtered through the nanofiltration/microfiltration membrane filter; Wherein, the electrolyzed water generator further includes: a cathode chamber water inlet, a cathode chamber water outlet, an anode chamber water inlet, an anode chamber water outlet, an electrolyzed water outlet, and a waste water outlet; Water enters the cathode chamber from the water inlet of the cathode chamber, and flows from the water outlet of the cathode chamber to the electrolyzed water outlet; Water enters the anode chamber from the water inlet of the anode chamber, and flows from the water outlet of the anode chamber to the waste water outlet; Also includes water inlet, combined water tank, diaphragm pump and water outlet; The combined water tank has a clean water storage tank and an electrolyzed water storage tank; After the clean water enters from the water inlet, after being filtered by the filter assembly, it enters the water inlet of the anode chamber, the water inlet of the cathode chamber and the water storage tank for clean water; The electrolyzed water flowing out of the electrolyzed water outlet enters the electrolyzed water storage tank; The water in the clean water storage tank and the electrolytic water storage tank passes through the diaphragm pump and flows out from the water outlet; It also includes a recovery box; the water flowing out of the waste water outlet flows into the recovery box; after being filtered by the filter assembly, the excess clean water also enters the recovery box; Also includes, The water inlet valve of the cathode chamber is arranged on the pipeline through which the filter assembly enters the water inlet of the cathode chamber; An anode chamber water inlet valve is arranged on the pipeline from the filter assembly to the anode chamber water inlet; The water inlet valve of the clean water tank is arranged on the pipeline from the filter assembly to the clean water storage tank; A recovery valve, arranged on the pipeline from the filter assembly to the recovery tank; The clean water outlet valve is arranged on the pipeline from the clean water storage tank to the diaphragm pump; The electrolyzed water outlet valve is arranged on the pipeline from the electrolyzed water storage tank to the diaphragm pump; An electrolyzed water level switch is provided in the electrolyzed water storage tank; When the electrolyzed water level switch is triggered, the anode chamber water inlet valve and the cathode chamber water inlet valve are connected, and the recovery valve and the water purification tank water inlet valve are closed; The clean water storage tank has a clean water level switch; When the clean water level switch is triggered, the anode chamber water inlet valve and the cathode chamber water inlet valve are closed, and the recovery valve and the clean water tank water inlet valve are connected; It also includes a control panel; the control panel has a water purification switch and an electrolysis water switch; When the water purification switch is turned on, the water purification outlet valve is connected, and the electrolyzed water outlet valve is closed; When the electrolyzed water switch is turned on, the electrolyzed water outlet valve is connected, and the purified water outlet valve is closed. 2. The electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system as claimed in claim 1, characterized in that: The water inlet of the anode chamber has a branch joint to adjust the amount of water entering the anode chamber. 3. The electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system as claimed in claim 2, characterized in that: The branch joint is a three-way structure, which are respectively the water port of the branch joint, the outlet of the water used and the outlet of the recovered water; The utilization water outlet is directly connected to the water inlet of the anode chamber; There is a flow regulating plug on one side of the recycled water outlet. 4. The electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system as claimed in claim 3, characterized in that: The recycled water outlet is connected to the waste water outlet. 5. The electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system as claimed in claim 1, characterized in that: It also includes a clean water shortage warning light, and when the clean water level switch is triggered, the clean water shortage warning light is turned on. 6. The electrolyzed water-oil-gas three-phase energy-saving micro-lubrication cooling system as claimed in claim 1, characterized in that: Wherein, the micro-spray device includes: an oil cup, a precision pneumatic pump, at least one frequency controller and an air source; The oil cup is set on the precision pneumatic pump, and the frequency controller controls the oil output frequency of the precision pneumatic pump; Compressed air passes through the air source, passes through the frequency controller, and flows into the precision pneumatic pump; Each of the precision pneumatic pumps is configured with one oil-water-air injection device. 7. The electrolyzed water-oil-gas three-phase energy-saving minimal quantity lubrication cooling system as claimed in claim 6, characterized in that: Wherein, the oil-water-air injection device includes an oil-water-air mixing control device and an energy-saving nozzle. 8. The electrolyzed water-oil-gas three-phase energy-saving minimal quantity lubrication cooling system as claimed in claim 7, characterized in that: The oil-water-gas mixing control device includes a regulating water valve and an oil-water-gas three-way module; Water enters the oil-water-gas tee module through the regulating water valve, and the regulating water valve controls the size of the water flow; The precision pneumatic pump pumps the oil out of the oil cup, and enters the oil-water-air tee module together with the compressed air. 9. The electrolyzed water-oil-gas three-phase energy-saving minimal quantity lubrication cooling system as claimed in claim 7, characterized in that: The energy-saving nozzle includes a nozzle body, a nested ring, a tee column, a sealing ring and a water-oil mixing Out of the tube; The oil and water are mixed and ejected from the water-oil mixing output pipe, and the gas enters the nozzle body and is ejected from the outside of the water-oil mixing output pipe through the nesting ring.