KR20050032941A - Salt in food waste removing device - Google Patents

Abstract

To provide an apparatus which efficiently removes salt in food waste by installing a separation membrane, thereby preventing reunion of decomposed salt, and also to prevent waste of electric power and improve salt removal efficiency by stopping removal of salt at a proper decomposition end point. An apparatus for removing salt of food waste comprises: a food waste salt removal unit(60) comprising a positive electrode part(10) connected to the anode of a power supply, a negative electrode part(20) connected to the cathode of the power supply, and a separation membrane(30) installed between the positive electrode part and the negative electrode part so that food waste is stored in a space between the positive electrode part and the separation membrane; and a container(70) in which the food waste salt removal unit is installed such that water(50) is stored in a space between the container and the food waste salt removal unit, wherein the container is equipped with a plurality of the food waste salt removal units, wherein the container has a cylindrical shape, and one cylindrical food waste salt removal unit is installed in the container, wherein the container has a rectangular box shape, and six rectangular box shaped food waste salt removal units are installed in the container, and wherein the food waste salt removal unit additionally comprises an exhaust means(65) for exhausting gas treated after electric voltage is impressed to the food waste salt removal unit.

Description

Salinity removal device of food waste {SALT IN FOOD WASTE REMOVING DEVICE}

The present invention relates to a salt removal device of food waste, and more particularly, to a salt removal device of food waste that can effectively control the decomposition end point of the salt while installing a separator to effectively treat the salt in the food waste. .

Currently, environmental pollution is a serious problem around the world, and food waste is one of the main causes of such environmental pollution. According to the Korea Environment Ministry, it is reported that 2900 tons of food waste is generated per day, which accelerates soil and water pollution, as well as causing secondary pollution problems such as generation of various odors and harmful gases.

In this regard, the Korean government has enacted all local governments to complete food waste recycling facilities by 2005 as a treatment plan to solve the pollution problem and recycle resources. Part of the problem is to resolve the salt in the food waste.

That is, even if the food waste is successfully fermented, the soil becomes acidified due to the salt in the food waste, which makes it difficult to use as compost, and even when the food waste is used as feed, the meat quality decreases and grows due to salt caused by a large amount of salt. It causes a lot of problems such as sluggishness and death of livestock.

Moreover, this problem is inevitably necessary to solve the problem, especially considering that Korean food waste contains a large amount of salt due to the unique Korean diet.

On the other hand, several methods for the treatment of conventional food waste have been prepared.

For example, there is an anaerobic composting system that carries food waste transportation, hopper injection, crushing, contaminant separation, aeration tank input, stirred fermentation (60 days), methane gas treatment, sludge dewatering, and compost production. It is a composting system installed in Uiwang-si, Paju-si, Gangneung-si, Gyeonggi-do, and puts food waste into an airless aeration tank, heats it, maintains the proper temperature, stirs it, methaneizes it, reduces it, and decomposes it by aerobic microorganisms. .

However, this technology has a problem of high facility construction cost, difficult operation technology after completion, a problem of causing second air pollution due to inability to process methane gas, and still high salinity of the produced compost.

Next, aerobic composting system using sawdust, which carries food waste, crushing food waste, compost fermentation plant, sawdust dilution (adjust moisture content 65-70%), stirred fermentation (60 days), sediment separation, and compost production This is a composting system installed in Ansan-si, Yeoju-si, Gangdong-gu, Seoul, Gyeonggi-do, and it is possible to control moisture by diluting dry organic matter such as sawdust for controlling moisture in food waste, and evenly in organic substance containing an appropriate amount of water. The oxygen supply is smoothed while stirring to supply oxygen, and the fermentation is simultaneously carried out by the yeast naturally at 60 to 70 ° C.

This technology is dedicated to pig processing in pig farms, which is relatively easy to install and easy to operate. However, compared to other technologies, this system has a large system installation area, has problems with moisture control sawdust, and salt concentration of mature compost. Is 10 to 30% or more, there is a problem that the utilization of the compost as described above is low.

Next, food waste transport, hopper injection, crushing, contaminant separation, desalination, sludge centrifugation dewatering, compost fermentation plant transfer, stirring fermentation (30 days), desorption sewage end treatment plant linkage, sewage separation, compost production There is a aerobic method composting system that goes through the process of composting, which is difficult to work due to odor because it is necessary to remove the contaminants, such as plastic bags, and there is a problem that only the good food waste such as restaurants can be processed, and the salt is physically There is a problem that the treatment efficiency of the salt is still not satisfactory because it is used to remove.

Next, food waste transportation, hopper injection, plastic bag destruction, plastic bag removal (vinyl removal pretreatment separate facility), debris removal (fog removal pretreatment separate facility), food waste destruction (bone, etc.), crushing, salt removal (food waste) Dilution and washing in industrial water), secondary separation and removal of plastic bags and contaminants, mixed manure agitation, sludge dewatering, compost fermentation plant transfer, stirred fermentation (period 60 days), desorption solution sewage treatment plant linked treatment (possible desalting solution economical), There is a composting system after the preliminary treatment of the tertiary segregation and the compost production (mature compost), which uses dilution using industrial water to solve the salt problem, but still has the limitation of not removing the salt itself. have.

As such, the salinity problem must be solved in the process of composting food waste, but there is no technique to satisfactorily remove the salinity, and further, the end point is set to appropriately remove the salinity, There has not yet been introduced a method for treating food waste that prevents the transport of decomposed ions and prevents recombination into salts, thereby increasing the decomposition efficiency and simultaneously removing odors and harmful gases.

Therefore, the present invention has been made to solve the above problems and needs,

The object of the present invention, unlike the prior art, by installing a separator to prevent recombination of the decomposed salt to efficiently remove the salt of food waste and also to stop the removal of salt at the appropriate end point to prevent waste of power It can remove salts with high efficiency, and it is inexpensive to install, and the installation cost is low because it is simple and easy to install. Also, it is a salt of food waste that can remove odor and harmful gas in food waste as well as salt. It is to provide a removal device.

An object of the present invention as described above, the positive electrode portion 10 is connected to the anode of the power source; A perforated negative electrode portion 20 connected to the cathode of the power supply; And a separator 30 formed between the positive electrode unit 10 and the negative electrode unit 20 and having food waste 40 stored in a space between the positive electrode unit 10 and the positive electrode unit 10. Device unit 60; And a container (70) having the unit (60) therein and storing water (50) in a space between the unit (60). .

And the container 70 is preferably provided with a plurality of salt removal device unit 60 of the food waste, the salt removal device of the food waste is the container 70 is cylindrical and one cylindrical unit therein Preferably, 60 is opened, and in the desalination device of the food waste, the container 70 is preferably a rectangular cylinder, and six rectangular cylinder-shaped units 60 are formed therein, and the unit 60 ) Is preferably further provided with a discharge means (65) for discharging the treated gas after voltage application, in this case, it is preferable that the undercurrent relay is attached to the power supply, the undercurrent relay is a salinity concentration of food waste Is 1 to 5%, it is more preferable to block the application of the current at 1/2 to 1/10 of the first applied current corresponding to the salt concentration.

Other objects, specific advantages and novel features of the invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

With reference to the accompanying drawings will be described in detail with respect to the salt removal device of food waste according to the present invention.

1 is a schematic view showing a salt removal device of food waste according to an embodiment of the present invention, Figure 2 is a schematic view showing a plane of the device without opening the lid of Figure 1;

As shown in FIGS. 1 and 2, the cylindrical separator 30 surrounds the positive electrode rod 10 and is spaced apart from each other, and the perforated negative electrode plate 20 surrounds and surrounds the separator 30. have. The positive electrode 10 and the negative electrode plate 20 are connected to a power source, and the power supply is provided with a DC UNDER CURRENT RELAY (DUCR) which is a DC undercurrent relay. As described above, the positive electrode rod 10, the separator 30, and the negative electrode plate 20 form one processing unit 60, and the food and drink between the separator 30 and the positive electrode rod 10 of the unit 60. Garbage 40 is filled. Cylindrical container 70 is contained in the unit 60, water 50 is introduced into the space made between the unit 60 and the interior of the container (70). On top of the container 70, as shown in Figure 1, the lid is covered.

Figure 3 is a schematic diagram showing a salt removal device of food waste according to another embodiment of the present invention, Figure 4 is a schematic diagram showing that the food waste is filled in the apparatus of FIG.

As shown in FIGS. 3 and 4, the separator 30 is opened at one side and the other side of the positive electrode plate 10, and the negative electrode plate 20, which is perforated in close contact with the separator 30 from the outside, is formed. Opened. The positive electrode plate 10 and the negative electrode plate 20 are connected to a power source, and a DC UNDER CURRENT RELAY (DUCR), which is a DC undercurrent relay, is established in the power source. As described above, the positive electrode plate 10, the separator 30, and the negative electrode plate 20 form one processing unit 60, and the food and beverage is separated between the separator 30 and the positive electrode plate 10 of the unit 60. Garbage 40 is filled. A rectangular cylindrical container 70 contains six units 60, and the outermost member of the other unit 60 adjacent to the negative electrode plate 20, which is the outermost member of one unit 60, is provided. The phosphorous electrode plate 20 has a structure connected under the unit 60. In such a container 70, water 50 is introduced therein. At this time, the negative electrode plate 20, which is the outermost member of the other unit 60 adjacent to the negative electrode plate 20, which is the outermost member of one unit 60, is closed by a lid at the top of the unit 60. When the food waste 40 is filled, the food waste 40 is not added to the water filled with the food waste 40.

As shown in Figures 1 to 4, the salt removal device of food waste according to the present invention, the food waste processing unit 60, the unit 60, the positive electrode portion 10, the separator 30 ) And the negative electrode unit 40 is basically included.

That is, at least one negative electrode portion 20 having a hole formed outside of the positive electrode portion 10 is opened, and the separator 30 is opened between the positive electrode portion 10 and the negative electrode portion 20. Food waste 40 is filled between the separator 30 and the positive electrode unit 20.

The positive electrode unit 10 is connected to the positive electrode of the power source, and the shape of the positive electrode unit 10 may vary depending on the shape of the unit 60. That is, as shown in FIGS. 1 and 2, the positive electrode 10 may be used as the positive electrode part 10, and as shown in FIGS. 3 and 4, the positive electrode plate as the positive electrode part 10. (10) can also be used. In this case, it is preferable to use carbon or iron in terms of slimming, that is, in terms of preventing the melting of the positive electrode rod or the positive electrode plate due to the progress of the electrolytic reaction by application of power, and also in terms of power saving or increase in processing efficiency. Do.

The perforated negative electrode portion 20 is connected to the cathode of the power supply, and a predetermined number of holes are drilled in a predetermined size, through which the water having ions passes.

As shown in FIGS. 1 and 2, it may be a perforated cylindrical negative electrode plate 20 wrapped around the positive electrode 10, and as shown in FIGS. 3 and 4, the positive electrode plate 10. It may be a negative electrode plate 20 which is opened at one side and the other side of the. In terms of power saving and processing efficiency, sus (SUS) or aluminum is used as the negative electrode unit 20. In addition, the height of the negative electrode unit 20 is preferably equal to the height of the positive electrode unit 10.

Next, the separator 30 is installed between the positive electrode unit 10 and the negative electrode unit 20, which serves to prevent recombination of salts after decomposition of salts.

In the case of the cylindrical unit 60 as shown in Figs. 1 and 2, the separator 30 is cylindrical and wraps around the positive electrode 10, and a rectangular cylinder as shown in Figs. In the case of the shape unit 60, the separator 30 is opened at predetermined intervals from one side and the other side of the positive electrode plate 10. In this case, as shown in FIGS. 1 to 4, all of the separators 30 are installed to closely contact the negative electrode unit 20.

In the cylindrical unit 60 or the square cylindrical unit 60, the height of the separator 30 is approximately equal to the height of the positive electrode unit 10 and the negative electrode unit 20. (30) It is preferable in terms of preventing the leakage to the outside and preventing the introduction of water 50 into the separator 30. In addition, the use of asbestos as the separator 30 prevents leakage of the food waste 40 to the outside of the separator 30, and prevents external water 50 from being introduced into the separator 30. Preferred at

In this way, the positive electrode portion 10, the negative electrode portion 20 and the separator 30 constitutes one food waste processing unit 60. In this unit 60, the overall size is appropriately set. By appropriately applying the voltage and current to be applied, the load of the anode portion 10 can be adjusted while increasing the power efficiency.

In the unit 60, as shown in Figures 1 to 4, it is preferable to have a discharge means 65 for discharging the gas generated from the electrolytic reaction after applying the voltage, the discharge means ( 65 is preferably a tube fixedly installed between the positive electrode portion 10 and the separator 30 to reach the bottom of the unit 60. As shown in FIGS. 3 and 4, the plurality of units 60 When it is opened, it is preferable that the pipe, which is the discharge means 65, is connected to all the cylinders 66 collecting the discharged gas.

Next, one or more of these units 60 are fixedly installed in the container 70. As shown in Figs. 1 and 2, in the case of the cylindrical unit 60, the cylindrical container 70 has the unit 60 therein, and as shown in Figs. In the case of the cylindrical unit 60, the rectangular cylindrical container 70 is provided with the unit 60, preferably six units 60 in terms of processing efficiency.

Water 50 is filled in the vessel 70 as described above, and then decomposition of the salt is performed when voltage is applied.

By the above configuration, the food waste desalination apparatus according to the present invention is easy to install, and the installation and installation cost is low, and a plurality of integration is also possible to facilitate the removal of salt of a large amount of food waste.

In particular, the food waste salt removing device according to the present invention does not process food waste directly with only the positive electrode portion and the negative electrode portion, but uses a separator to prevent recombination of the decomposed salt, thereby increasing the efficiency of salt decomposition. By quickly reaching the end point of decomposition as described below, the applied power is reduced and its processing efficiency is excellent.

Hereinafter, the operation of the food waste salt removing device according to the present invention will be described in detail.

In the food waste salt removing apparatus according to the present invention, first, when voltage and current are applied to the positive electrode unit 10 and the negative electrode unit 20 connected to a power source, the salt in the food waste inside the separator 30 is electrolyzed.

At this time, when the salinity concentration of the food waste is 1 to 5%, the application of the current is cut off at 1/2 to 1/10 of the first applied current corresponding to the salinity concentration.

That is, when the salinity of food waste is 1%, for example, the current is cut off at a point corresponding to 1/2 of the current applied first, and when the salinity of food waste is 5%, for example, Block the application of current at one-tenth of the current applied.

After the current is cut off, there is almost no salinity, and when current is applied thereafter, electrolysis of water begins to occur, resulting in waste of power.

In the present invention, by setting the end point of the salt removal as described above, it is to increase the processing efficiency compared to the applied power. The current blocking is performed by using an under current relay, for example, a DC UNDER CURRENT RELAY (DUCR).

In this electrolysis process, using the separator 30 such as asbestos, the food waste 40 must be prevented from leaking to the outside of the separator 30 and the input of water 50 outside the separator 30. It is preferable to proceed with decomposition.

On the other hand, as the electrolysis is performed, not only salts are decomposed, but also substances causing harmful odors generated from food waste and ammonia, sulfide gases, and other harmful gas substances are decomposed to remove odors or harmful gases.

By operating the food waste desalination apparatus of the present invention as described above, by preventing the recombination of the decomposed salt, and easily set the end point of salt decomposition, unlike the prior art it may not cause even the electrolysis of water, It is possible to considerably prevent power waste, to remove odors and harmful gases at the same time, and also to easily collect substances such as chlorine generated by removing salts and to recycle them as disinfectants. Sodium hydroxide obtained by the food waste desalination apparatus according to the present invention can be recycled also in the production of soap, etc., and eventually has a high economic value.

According to the food waste salt removing device of the present invention, by installing a separator to prevent recombination of the decomposed salts, it is possible to efficiently remove the salts of the food waste, and to stop the removal of salts at an appropriate end point, thereby reducing the waste of power. It can effectively remove salts while preventing the cost of the facility, and it is easy to install and easy to install.The cost of installation is also low.It can remove odors and harmful gas in food wastes as well as remove salts. By recycling the by-products obtained from, the effect of high economic value is achieved.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as fall within the spirit of the invention.

1 is a schematic diagram showing a salt removal device of food waste according to an embodiment of the present invention,

FIG. 2 is a schematic view showing a plane of the device without the lid of the device of FIG. 1;

Figure 3 is a schematic diagram showing a salt removal device of food waste according to another embodiment of the present invention,

Figure 4 is a schematic diagram showing that the food waste is filled in the apparatus of FIG.

Explanation of the Main References

10: positive electrode portion 20: negative electrode portion

30: Insulation 40: Food waste

50: water 60: food waste treatment unit

65: discharge means 70: container

Claims (7)

A positive electrode unit 10 connected to the anode of the power source; A perforated negative electrode portion 20 connected to the cathode of the power supply; And a separator 30 formed between the positive electrode unit 10 and the negative electrode unit 20 and having food waste 40 stored in a space between the positive electrode unit 10 and the positive electrode unit 10. Device unit 60; And a container (70) having the unit (60) therein and storing water (50) in a space between the unit (60). The method of claim 1, wherein the container 70, Salinity removal device for food waste, characterized in that it comprises a plurality of salinity removal unit unit (60) of the food waste. According to claim 1, The salt removal device of the food waste, Salinity removal device for food waste, characterized in that the container (70) is cylindrical and one cylindrical unit (60) is opened therein. According to claim 1, The salt removal device of the food waste, The container (70) is a rectangular barrel, and the salinity removal device of food waste, characterized in that six rectangular cylindrical unit (60) is opened therein. The method of claim 1, wherein the unit 60, Salinity removal device for food waste, characterized in that it further comprises a discharge means for discharging the treated gas after voltage application. The power supply according to any one of claims 1 to 5, wherein Salinity removal device of food waste, characterized in that the low current relay is attached. The method of claim 6, wherein the undercurrent relay, When the salinity concentration of the food waste is 1 to 5%, the salt removal device of the food waste, characterized in that to cut off the application of the current at 1/2 to 1/10 of the first applied current corresponding to the salt concentration. .