JPH0631897U - Industrial effluent recycling equipment - Google Patents

Abstract

(57) [Summary] (Corrected) [Purpose] Metals (A) in wastewater without using chemicals such as sodium hypochlorite and chlorine
u, Ag, Cu, Ni, etc.) can be recovered in the form of powder, and the waste water after treatment can be recycled as water for reuse as industrial water. . A device for treating industrial effluent containing metal ions and a substance capable of decomposing by a photo ozone oxidation reaction, wherein a photo ozone oxidation reaction tank 4, a filter 14 and a desalination tank are connected in series. Connect and connect the conductivity meter 19 to the drain of the processed liquid.
Is provided.

Description

[Detailed description of the device]

[0001]

【Technical field】

 The present invention is an industrial effluent recycling device, and more specifically, it oxidizes and decomposes industrial effluent containing metal ions and substances that can be decomposed by photo-ozone oxidation to solidify the produced metal oxide powder and metal scrap. The present invention relates to a recycle device capable of reusing the water obtained by demineralizing the salts present in the treated liquid as desalination, and reusing the resulting water.

[0002]

[Background technology]

 Cyanide compounds of various metal ions such as gold, silver, copper, zinc and nickel are contained in the industrial effluent discharged in the plating process of surface treatment of electronic parts, printed circuit boards, decorative products, machine parts, etc. In addition to these, surfactants, degreasing agents, microorganisms, organic substances such as oil, and metal scraps are mixed. In particular, cyanide compounds are extremely poisonous, so industrial wastewater must be completely rendered harmless before being discharged into rivers and sewers.

The conventional drainage treatment is mainly performed by an alkali chlorine method in which sodium hypochlorite (NaOCl) is added to the drainage. In that case, the chemical reaction formula can be expressed as follows using CuCN as an example.

2CuCN + 5NaOCl + H ₂ O → 2CO ₂ + N ₂ + 2CuOH + 5NaCl (1)

As can be seen from the equation (1), in order to oxidatively decompose 1 kg of CuCN, it is necessary to add 7.2 kg of NaOCl. The metal hydroxide (CuOH) produced by this oxidative decomposition treatment is subjected to neutralization / coagulation treatment, and then precipitated and filtered to be separated and recovered as sludge. This sludge contains a large amount of water, and even if a dehydrator such as a filter press is used, the water content is limited to about 70%, but in any case, these sludges are not treated in any special way. Until now, it has been dumped at a disposal site.

On the other hand, the filtrate contains a residue of sodium hydroxide added for the purpose of neutralization and the purpose of preventing the danger associated with the generation of cyan gas, or salts thereof such as NaCl generated as a result thereof, as well as organic substances and the like. Although it is contained at a high concentration, there is currently no cheap treatment method, so it is released by neutralizing it again.

As described above, the conventional method for treating the drainage of the cleaning liquid during the plating treatment uses a large amount of sodium hypochlorite, chlorine, sodium hydroxide, a flocculating precipitant, etc. Cause the large amount of sludge discharge and the generation of effluent water with increased salt concentration. Discharging treated water containing salts and organic substances to rivers also pollutes rivers and raises the BOD value of the water.

Further, when the injection amount of the chemicals (NaOCl, Cl ₂ ) is not appropriate, it has been observed that an effluent having a dangerous cyanide concentration flows into the river, while the sludge ash is discarded. Given the current situation where it is becoming difficult to secure a space, it is urgently required to develop a new wastewater treatment system that does not cause such problems.

[0009]

[Disclosure of device]

 As a result of intensive studies to solve the problems of the conventional treatment methods, the present inventors have found that metals such as sodium hypochlorite and chlorine and coagulation-precipitating agents are not used, and the metals contained in the drainage are not used. (Au, Ag, Cu, Ni, etc.) can be recovered in the form of powder, and the wastewater after treatment can be recycled as water so that it can be reused as industrial water. Succeeded in providing.

That is, the present invention is an apparatus for treating and regenerating industrial effluent containing metal ions and a substance capable of being oxidatively decomposed by a photo-ozone oxidation reaction, which comprises a photo-ozone oxidation reaction tank, a filter, and The present invention provides a recycling apparatus for industrial waste liquid, which is characterized in that a desalting tank is connected in series, and a conductivity meter is provided at the discharge outlet of the waste liquid after treatment. According to the present invention, as the above-mentioned photo-ozone oxidation reaction tank, an ultraviolet lamp provided in a quartz glass tube and the air converted into ozonized air in the quartz glass tube are diffused into the tank. Provided is a recycling apparatus for industrial waste liquid, which is provided with a photo-ozone oxidation reaction tank equipped with a diffusing pipe.

The apparatus of the present invention will be described in more detail below. In the photo-ozone oxidation reaction tank of the recycling apparatus according to the present invention, the cyan compound of each metal ion in the effluent is, for example, a copper cyan compound (CuCN). Detoxified by the photo-ozone oxidation reaction of.

2CuCN + 5O ₃ + 3H ₂ O → 2Cu (OH) ₂ + 2H ₂ CO ₃ + N ₂ + 5O ₂ (2) The metal hydroxide (Cu (OH) ₂ ) produced by the oxidation reaction of the formula ( ₂ ) is Under the action of ultraviolet rays, it is further oxidized according to the reaction of the following formula (3) to become an insoluble metal oxide. This metal oxide is separated and collected by a filter. Cu (OH) ₂ → CuO + H ₂ O (3)

That is, the metals (Au, Ag, Cu, Fe, Ni, etc.) contained as a cyanide compound or a cyan complex of a metal ion in the waste liquid are treated as sludge having a high water content and a high salt concentration. Instead, it is separated and recovered as a solid metal oxide, so that the valuable metal can be reused.

On the other hand, an organic substance is converted into an organic acid by a photo-ozone oxidation reaction, and finally converted into carbon dioxide gas and water. Further, CN in a free state is converted into cyanic acid, carbonic acid and nitrogen. Be disassembled. Various cations and anions present in the treatment liquid are ion-exchanged with H ⁺ or OH ⁻ by the ion exchange resin, or desalted by the reverse osmosis membrane.

As described above, according to the device of the present invention, the cyanide compound, the cyanide compound, the heavy metal, the organic compound, and the like can be used for industrial waste liquid containing a cyanide compound by utilizing the photo-ozone oxidation reaction without adding any chemicals. Process of decomposing, oxidizing, detoxifying, and insolubilizing organic substances, collecting metal oxides deposited in the liquid with a filter, and desolving ions dissolved in the liquid with an ion-exchange resin, and reusing as water These steps can be performed in series by combining the three steps with the step of performing. That is, by connecting the optical ozone reaction tank, the filter, and the ion exchange tank in series, it is possible to continuously purify the industrial waste liquid without chemical injection. The present invention makes it possible to recover valuable metals that were previously discarded as sludge, and reuse the discharged washing effluent as water, and in the device of the present invention, the only operating energy source is electricity. Therefore, it is possible to easily and reliably recover valuable metals from industrial effluents and recycle water even at business establishments that do not employ effluent treatment engineers.

Hereinafter, with reference to FIG. 1, one embodiment of a drainage recycling apparatus according to the present invention will be described in detail.

[0017]

【Example】

 FIG. 1 is a flow sheet showing a recycling device according to the present invention. In the figure, 1 is a drainage storage tank, 4 is a photo-ozone oxidation reaction tank, 14 is a filter, 17 and 18 are a cation exchange column and an anion exchange column, and 19 is a conductive layer. It is a meter, and each of these devices is connected in series.

The waste liquid storage tank 1 temporarily stores the waste liquid for treatment, and the waste liquid is sent to the optical ozone oxidation reaction tank 4 while measuring the flow rate by the pump 3 via the flow meter 22. It has become.

In the optical ozone oxidation reaction tank 4, an ozone generator having an ultraviolet ray lamp 5 in which a lighting device 9 is connected in a quartz glass tube 6 is installed, and an ultraviolet lamp 5 in the quartz glass tube 6 is installed. Air (oxygen) is sent from the compressor 10 through the desiccant 11 by the flow meter 23 to measure the flow rate into the space between the quartz glass tube 6 and the quartz glass tube 6.

As the ultraviolet lamp 5, a low-pressure mercury lamp that emits a bright line with a wavelength of 184.9 nm is suitable.

Oxygen in the air sent from the compressor 10 in the quartz glass tube is converted to ozone by ultraviolet rays, and the generated ozone is guided to the lower part of the reaction tank as ozonized air and treated by the diffuser tube 8. Bubbles are ejected into the drainage.

The above-mentioned ultraviolet rays also permeate the quartz glass tube and contribute to the reaction of converting the metal hydroxide in the waste liquid into a metal oxide. The ozonized air sent into the treated effluent comes into contact with metal ions, cyan complex compounds, organic substances, etc. under irradiation of ultraviolet rays, and the metals undergo an oxidative decomposition reaction as shown in the above formula (2) to cause metal water. It becomes an oxide and further becomes an insoluble metal oxide by the reaction as exemplified in the above formula (3) by the action of ultraviolet rays, which is captured and recovered by the filter of the filter 14.

The storage tank 12 is for temporarily storing the waste liquid processed in the photo-ozone oxidation reaction tank 4, and the processed waste liquid is sent to the filter 14 by the pump 13. The filter 14 may be either horizontal or vertical, and insoluble metal oxides produced in the optical ozone oxidation reaction tank and solid matters such as mixed metal scraps are filtered and separated by this filter. . A sampling device 20 is installed on the outlet side of the processing effluent of the filter 14, and when it is judged that the oxidation reaction is insufficient based on the sampling of the processing effluent in this device and the analysis result thereof, The adjustment valve 25 on the side of the flow path leading to the ion exchange towers 17 and 18 is closed, and the adjustment valve 24 on the side of the flow path leading to the photo-ozone oxidation reaction tank is opened, and the treated effluent is returned to the photo-ozone oxidation reaction tank 4 and again. Allow the oxidation reaction to complete. A conductivity meter 19 is installed on the outlet side of the effluent of the cation exchange column 17 and the anion exchange column 18.

The water quality of the treated effluent is judged from the results measured by this conductivity meter. Normally, the electric conductivity of raw water is about 500 to 2000 μS / cm, but by the device of the present invention, the treated effluent is discharged as demineralized water having an electric conductivity of 50 μS / cm or less. The conductivity of general tap water is about 120 to 300 μS / cm, but when the conductivity of the treated wastewater exceeds 200 μS / cm, the ion exchange towers 17 and 18 are replaced with new towers. The replaced saturated ion exchange tower will be regenerated separately at the reprocessing plant to prepare for the next use. The ion exchange towers 17 and 18 may not be separate ion exchange towers but may be one tower packed with a cation exchange resin and an anion exchange resin.

An example of the usage of the device of the present invention for the copper plating cleaning liquid and the silver cyanide plating cleaning liquid as one embodiment of the present invention will be described. Using a light ozone reaction tank of about 4 L capacity equipped with a 40 watt low-pressure mercury lamp and a cartridge type pleated membrane filter (pore size 1 to 10 μm, length 25 to 75 cm) as an element of the filter, air was supplied. Table 1 shows the analysis results of the effluent that was reacted for 1 hour while being supplied to the space between the low pressure mercury lamp and the quartz glass tube at a flow rate of 1 liter per minute. The precipitate captured by the filter was a copper oxide powder.

[0026]

[Table 1]

Next, Table 2 shows the analysis results of the silver cyanide plating effluent which was reacted with the silver cyanide plating cleaning liquid under the same conditions as the copper plating cleaning liquid. The deposit was a silver oxide powder deposited by the photo-ozone oxidation decomposition of the dissolved silver cyanide complex.

[0028]

[Table 2]

From the above results, it is understood that the electric conductivity of the treated water treated from the outlet of the ion exchange tower is much smaller than the electric conductivity (120 to 300) of general tap water. Also, according to this example, the amount of cyanide decomposed by one 40-watt low-pressure mercury lamp was about 20 to 40 ppm per 10 minutes. It was confirmed that the residence time of the reaction becomes longer as the cyan concentration becomes higher, but the residence time can be shortened by using an ozonizer in addition to the low pressure mercury lamp.

[0030]

【effect】

 As described above, the industrial effluent recycling apparatus according to the present invention enables continuous treatment of effluent by connecting the photo-ozone oxidation reaction tank, the filter and the desalination tank in series. It is possible to purify the effluent to a conductivity equal to or lower than that of ordinary tap water without using such an additive agent. As a result, there is no need for a device for storing and injecting a chemical solution such as a conventional device and various measurement control equipment associated therewith, which brings an advantage that the entire processing device is downsized.

Since the apparatus of the present invention uses only electric power as energy, it does not require a special wastewater treatment engineer and can be easily installed in small and medium-sized business establishments.

Further, since various metals are recovered in the form of solid metal oxides having a low water retention capacity, they can be reutilized as a metal remarkably easily, and further, the sludge of the conventional method can be obtained. It rarely occurs and therefore its contribution to waste reduction is extremely large.

[Brief description of drawings]

FIG. 1 is a flow sheet showing a drainage recycling apparatus according to the present invention.

[Explanation of symbols]

 1 Waste liquid storage tank 3, 13 Pump 4 Optical ozone oxidation reaction tank 5 Ultraviolet lamp 6 Quartz glass tube 8 Diffuser tube 9 Lighting device 10 Compressor 11 Desiccant 12 Storage tank 14 Filter 15 and 16 Flowmeter 17 Cation exchange tower 18 Anion Ion exchange tower 19 Conductivity meter 20 Sampling equipment 22,23 Flow meter 24,25 Regulator valve 26 Treated water

Claims (2)

[Scope of utility model registration request] 1. An apparatus for treating industrial effluent containing metal ions and a substance capable of decomposing by a photo ozone oxidation reaction, which comprises a photo ozone oxidation reaction tank, a filter and a desalination tank in series. An industrial waste liquid recycling apparatus, which is provided with an electric conductivity meter at an outlet of the waste liquid after being connected and treated. 2. The optical ozone oxidation reaction tank comprises an ultraviolet lamp provided in a quartz glass tube and an air diffuser for diffusing the air converted into ozonized air in the quartz glass tube into the tank. The industrial waste liquid recycling apparatus according to claim 1, which is provided.