JP2016064380A - Solid-liquid separation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solid-liquid separation device which separates a solid-liquid mixture into solid and liquid using a liquefied substance prepared by pressurizing gaseous substance to the saturated vapor pressure thereof or higher, the running cost of which is reduced by reducing an amount of use of the liquefied substance and the safety of which can be improved.SOLUTION: There is provided the solid-liquid separation device for individually separating a solid-liquid mixture using a gaseous substance which is converted to a liquid at a saturated vapor pressure or higher. The device comprises: a compressor 5 for compressing the substance; a chiller 34 for liquefying the high-temperature high-pressure substance after being compressed ; an accumulator 6 for storing a liquefied substance; a valve 11 for controlling the flow of the liquefied substance at a position downstream of the accumulator; an atomizer capable of spraying the liquefied gas as a droplet at a position downstream of the valve; a treatment tank 2 capable of being filled with the mixture and having the vaporizer at an upper part; a filter for preventing outflow of a solid from the treatment tank 2; and a vaporizer 7 for vaporizing the substance from the mixture flowing out from the treatment tank 2. The upper space in the treatment tank 2 is filled with a substance in a gaseous state.SELECTED DRAWING: Figure 1

Description

The present invention relates to an apparatus for independently separating a solid and liquid mixture.

As a background art in this technical field, Patent Document 1 and Patent Document 2 that use phase change of an organic solvent to separate a solid and liquid mixture are disclosed.
(Patent Document 1) describes a device that regenerates used activated carbon using a liquid organic solvent at room temperature and normal pressure. The organic solvent used for washing is distilled to increase purity, and is used again to regenerate activated carbon. A configuration is disclosed.

(Patent Document 2) discloses a method in which a gaseous substance is liquefied at normal temperature and pressure, mixed with sewage sludge, and deodorized.

JP 07-313874 A Republished WO2008 / 093707

  (Patent Document 1) discloses a method of regenerating an adsorbent by immersing activated carbon in a large amount of an organic solvent and distilling and recycling the organic solvent containing impurities.

  (Patent Document 2) discloses a method for extracting malodorous components by immersing sewage sludge in liquefied gas, separating the malodorous components by changing the phase of the used liquefied gas, and reusing the liquefied gas. Yes.

  In (Patent Document 1) and (Patent Document 2), since a target substance is extracted by immersing a mixture of solid and liquid in an organic solvent, a large amount of organic solvent is required for the extraction process, and the processing cost is It increases and the risk increases when it leaks.

Therefore, the present invention provides a solid-liquid separation device that can reduce the amount of an extraction medium such as an organic solvent necessary for solid-liquid separation.

In order to solve the above-mentioned problems, the present invention uses a substance that is a gas at room temperature and becomes a liquid when the saturated vapor pressure is exceeded, and in the solid-liquid separation device that separates a solid and a liquid mixture independently, A compressor for compressing the material, a cooler for liquefying the material that has been compressed to high temperature and pressure, an accumulator for storing the liquefied material, and a liquefied material downstream of the accumulator A valve for restricting the flow, a sprayer for spraying liquefied gas as droplets downstream of the valve, a treatment tank equipped with the sprayer at the top, which can be filled with the mixture,
A filter for preventing solids from flowing out of the treatment tank and a vaporizer for vaporizing a substance from the mixed solution flowing out of the treatment tank, wherein an upper space is filled with the substance in a gaseous state in the treatment tank. It is what.

In order to solve the above-mentioned problem, the present invention uses a substance that is a gas at room temperature and becomes a saturated vapor pressure or higher, and in a solid-liquid separation device that separates a solid and a liquid mixture independently. A cooler for liquefying the substance that is a high-pressure gas, a pump for feeding the liquefied substance, an accumulator for storing the liquefied substance, and a flow of the substance liquefied downstream of the accumulator A valve for limiting, a sprayer for spraying liquefied gas as droplets downstream of the valve, a treatment tank capable of being filled with the mixture, and provided with the sprayer at the top, a filter for preventing solids from flowing out of the treatment tank, A vaporizer for vaporizing the substance from the mixed solution flowing out from the treatment tank is provided, and an upper space is filled with the substance in a gaseous state in the treatment tank. It is intended to.
Furthermore, the present invention is characterized in that in the solid-liquid separation device, a heat exchanger is provided that provides the latent heat necessary for vaporizing the substance with the latent heat generated when the substance is liquefied.
Furthermore, in the solid-liquid separator, the present invention is characterized in that the heat exchanger for vaporizing the substance and the heat exchanger for liquefying the substance are connected by a refrigeration cycle using a refrigerant.
Furthermore, the present invention is a solid-liquid separator, wherein the substance is dimethyl ether.
Furthermore, in the solid-liquid separator, the present invention is characterized in that the mixture is a used adsorbent used in water treatment.
Furthermore, in the solid-liquid separator, the present invention is characterized in that the mixture is used activated carbon used in water treatment.
Further, in the solid-liquid separator according to the present invention, the sprayer is a horizontally installed pipe, and is connected to an upstream flow path with a connecting pipe that is rotatable at an upper part of the center of gravity of the pipe. Two spouts are provided, the spouts are installed at a point-symmetrical position with the connecting pipe as the central axis, and the direction of the spout is substantially perpendicular to the pipe, and is vertically downward to horizontal By setting the position, the sprayer is rotated by the fluid force of the fluid discharged from the ejection port.

According to the present invention, in a solid-liquid separation apparatus that separates a mixture of solid and liquid using a liquefied substance that has become a liquid by pressurizing a gaseous substance at normal temperature and pressure to a saturation vapor pressure or higher, the substance having a saturated vapor pressure is used. The amount of liquefied material in the processing tank is reduced by spraying droplets of the liquefied material from the top vertically onto the mixture in the processing tank filled with the above gas and extracting the liquid in the mixture using the generated droplets. In addition, a solid-liquid separator that can reduce running costs and improve safety can be provided.

It is an example of the block diagram of the solid-liquid separator of this invention. It is an example of the internal structure of the processing tank which comprises the solid-liquid separation apparatus of this invention. It is another example of the block diagram of the solid-liquid separator of this invention.

  According to the present invention, it is possible to separate a solid and liquid mixture into a solid and a liquid independently. Specifically, it can be applied to various solid-liquid separations such as dewatering sludge generated by water treatment, purification of oil-contaminated soil, dewatering / deoiling from plankton.

  Further, according to the present invention, the adsorbed impurities can be desorbed with high efficiency from the used adsorbent used for water treatment. Therefore, as an embodiment of the present invention, an activated carbon regenerator that regenerates used activated carbon is taken as an example. I will give you a description. Examples of substances that can be used in this embodiment include ethyl methyl ether, formaldehyde, ketene, acetaldehyde, etc., but dimethyl ether (boiling point is about −24 ° C. and saturation vapor pressure at 24 ° C. is about 0.58 MPa). (Hereinafter referred to as “DME”) is easy to handle and can be kept low in running cost. Therefore, in the embodiments of the present invention, DME will be described as an example. Embodiments of the present invention will be described below with reference to the accompanying drawings.

Embodiments of the present invention will be described below with reference to the drawings.
(First Example)
The configuration of an activated carbon regenerator that is one of the objects to which the present invention is applied will be described with reference to FIGS. 1 and 2. FIG. 2 shows the internal structure of the processing tank 2 shown in FIG.

  In the embodiment shown in FIG. 1, the DME is circulated in the apparatus by the compressor 5 with a phase change, and the flow path and the inside of the devices are held at the saturated vapor pressure of the DME. First, gaseous DME gas is pressurized by the compressor 5 and heated. The pressurized DME gas is subjected to heat removal by the cooler 34 and sent to the high temperature side passage 33 of the heat exchanger 7. The DME gas in the high temperature side channel 33 is cooled while transferring the latent heat at the time of liquefaction to the low temperature side channel, and the entire amount becomes liquid and is discharged as liquefied DME. The liquefied DME is guided to the valve 11 via the accumulator 6, the flow rate is adjusted, and the liquefied DME is sent to the treatment tank 2 filled with DME gas. A sprayer 20 having a structure capable of rotating in the horizontal direction around the vertical direction is provided in the upper part of the processing tank 2, and liquefied DME is sprayed as droplets from the rotating sprayer 20 into the processing tank 2. A filter 45 for preventing solid outflow is installed at the bottom of the treatment tank 2 shown in FIG. 2, and the used activated carbon 50 to be treated is filled at the top thereof. The droplets discharged from the sprayer 20 fall by gravity, come into contact with the used activated carbon, flow down while desorbing water and organic substances adhering to and adsorbing to the activated carbon, and discharged from the lower part of the processing tank 2 13 leads to.

  When the liquefied DME containing impurities is reduced in pressure when passing through the valve 13, a part of the liquefied DME is vaporized to form a two-phase flow with a lowered temperature, and is led to the low temperature side flow path of the heat exchanger 7. The DME containing impurities receives the energy of the latent heat of vaporization in the heat exchanger 7 and continuously vaporizes, and the impurities are concentrated in the low temperature side flow path and become precipitates 31 when the solubility in DME staying is exceeded. To precipitate.

  Since the vaporized DME gas is sent again by the compressor 5 and circulated, this embodiment is a phase change cycle of DME. Therefore, in this embodiment, the cycle of this cycle can be circulated to improve the desorption rate of the activated carbon, and the desorption is performed inside the treatment tank 2 by contact with the liquefied DME of the droplets. This can reduce the running cost and improve safety. Further, the latent heat of vaporization and the latent heat of condensation exchanged by the heat exchanger 7 are almost equal, and heat exchange can be performed with a minute temperature difference, so a large-scale heat source or cooling source corresponding to the latent heat is unnecessary.

  Here, the principle by which droplets of liquefied DME can be sprayed while the inside of the processing tank 2 is filled with DME gas will be described. First, the upstream pressure can always be kept above the saturated vapor pressure by the valve 11, and the liquefied DME is held in the accumulator 6, so that even when the operating state of the compressor 5 fluctuates, it is discharged from the sprayer 20. DME always maintains a liquid state and can be ejected as droplets. Further, since the processing tank 2 is maintained at a saturated vapor pressure by the DME gas, the discharged droplets are discharged as liquid from the bottom of the processing tank 2 without being vaporized. Further, the opening degree of the valve 13 installed downstream of the processing tank 2 needs to be adjusted so that the passage flow rate of the valve 13 becomes equal to the passage flow rate of the valve 11. If the flow rates are different, for example, if the passage flow rate of the valve 13 is larger than the passage flow rate of the valve 11, the pressure inside the processing tank 2 decreases, so that the droplets are vaporized, and the liquid necessary for regeneration of the activated carbon. Contact is impossible. On the other hand, when the passage flow rate of the valve 13 is smaller than the passage flow rate of the valve 11, the DME gas in the treatment tank 2 is liquefied and stored, so that the DME circulated in the activated carbon regenerator is insufficient.

  In addition, as for the sprayer 20, the present invention can be implemented even with a fixed sprayer. However, when the rotary sprayer is used, the uniformity of the spray amount of the droplets on the activated carbon is improved, so that the regeneration time of the activated carbon can be shortened. Although external force such as a motor may be used as the driving force for rotation, chemical resistance is required for the inside of the treatment tank 2, so that it can be rotated by using a structure that rotates using the fluid force generated during injection. The number of necessary equipment parts can be greatly reduced, and the frequency of failures can be reduced. In order to rotate the sprayer with fluid force, the center of gravity of the pipe constituting the sprayer is used as a rotation axis, and at least near both ends of the pipe, a discharge port may be provided in a direction that is symmetric with respect to the rotation axis. May be installed so that its direction is substantially perpendicular to the pipe and further between the vertically downward direction and the substantially horizontal direction.

  Further, when the used activated carbon is taken out, if the valve 11 is closed and the operation of the compressor 5 is continued, most of the DME in the cycle is confined in the accumulator 6, so the valve 13 is closed after the DME is recovered and then processed. Leakage of DME to the outside can be reduced by opening the tank.

The cooler 34 used for cooling the DME is a small cooler because the purpose is to remove the energy increase in the DME cycle due to the operation of the compressor 5.
Note that the pressure and temperature displays in the figure show qualitative changes, and the present invention is not limited to these values.

(Second embodiment)
FIG. 3 shows another embodiment of the present invention, which is an example in which a pump capable of suppressing initial cost and running cost is used instead of a compressor for circulating DME. The DME phase change cycle of the present embodiment is substantially the same as that of the embodiment of FIG. 1 except as specifically described below, and is different in that a refrigeration cycle using a refrigerant is connected to transfer the latent heat of the DME.

  First, on the DME cycle side, liquefied DME is fed by the pump 1 and guided to the valve 11 via the accumulator 6. The liquefied DME that has passed through the valve 11 is sprayed as droplets by a sprayer inside the treatment tank 2 filled with the DME gas having a saturated vapor pressure, contacts the activated carbon, dissolves impurities, and then flows from the bottom of the treatment tank 2. Discharged. The liquefied DME containing the discharged impurities passes through the valve 13 as a liquid and is sent to the low-temperature channel of the heat exchanger 3. In the heat exchanger 3, the liquefied DME that has been sent is vaporized by receiving latent heat of vaporization from the refrigerant flowing in the high-temperature channel 36, and impurities are separated as precipitates 31. The vaporized DME gas is guided to the high temperature side flow path of the heat exchanger 4, and the condensed latent heat is transmitted to the refrigerant flowing through the low temperature side flow path 37 to become liquefied DME, which is sent again by the pump 1 and circulated. .

On the other hand, on the refrigeration cycle side through which the refrigerant flows, the gaseous refrigerant is heated and boosted by the compressor 5, removed from heat by the cooler 34, and then sent to the high temperature side flow path 36 of the heat exchanger 3. In the heat exchanger 3, the refrigerant is liquefied by transmitting the latent heat of condensation of the refrigerant to the DME. Since the liquefied refrigerant is decompressed by the expansion valve 21, a part of the refrigerant is vaporized to become a two-phase flow and the temperature is lowered. The refrigerant that has become a two-phase flow is sent to the low temperature side flow path 37 of the heat exchanger 4, receives condensation latent heat from the DME gas in the high temperature side flow path, and the refrigerant is vaporized. The vaporized refrigerant is compressed again by the compressor 5 and circulated.
Therefore, according to this embodiment, the phase change of DME can be achieved at low cost by using an existing refrigerant, a compressor for the refrigerant, and an inexpensive DME pump without using a DME gas compressor. A cycle can be realized.

DESCRIPTION OF SYMBOLS 1 ... Pump 2 ... Processing tank 3 ... Heat exchanger 4 ... Heat exchanger 5 ... Compressor 6 ... Accumulator 20 ... Nebulizer 21 ... Expansion valve

Claims (8)

In a solid-liquid separator that uses a substance that is a gas at room temperature and becomes a liquid by exceeding the saturated vapor pressure, and separates the mixture of solid and liquid independently.
A compressor for compressing the substance;
A cooler for liquefying the material that has been compressed to high temperature and pressure;
An accumulator for storing the liquefied substance;
A valve for restricting the flow of liquefied material downstream of the accumulator;
A sprayer that sprays liquefied gas as droplets downstream of the valve, a treatment tank that can be filled with the mixture and has the sprayer on top;
A filter for preventing the outflow of solids from the treatment tank;
A vaporizer for vaporizing the substance from the mixed solution flowing out of the treatment tank;
A solid-liquid separation device, wherein an upper space is filled with the substance in a gaseous state in the treatment tank. In a solid-liquid separator that uses a substance that is a gas at room temperature and becomes a liquid by exceeding the saturated vapor pressure, and separates the mixture of solid and liquid independently.
A cooler for liquefying the substance which is a high-pressure gas;
A pump for feeding the liquefied substance,
An accumulator for storing the liquefied substance;
A valve for restricting the flow of the material liquefied downstream of the accumulator;
A sprayer that sprays liquefied gas as droplets downstream of the valve, a treatment tank that can be filled with the mixture and has the sprayer on top;
A filter for preventing the outflow of solids from the treatment tank;
A vaporizer for vaporizing the substance from the mixed solution flowing out of the treatment tank;
A solid-liquid separation device, wherein an upper space is filled with the substance in a gaseous state in the treatment tank. In the solid-liquid separator of Claim 1 or Claim 2,
A solid-liquid separation device comprising a heat exchanger that provides latent heat required for vaporizing the substance with latent heat generated when the substance is liquefied. In the solid-liquid separator of Claim 1 or Claim 2,
A solid-liquid separation device, wherein a heat exchanger for vaporizing the substance and a heat exchanger for liquefying the substance are connected by a refrigeration cycle using a refrigerant. In the solid-liquid separator of Claim 1 or Claim 2,
A solid-liquid separator characterized in that the substance is dimethyl ether. In the solid-liquid separator of Claim 1 or Claim 2,
A solid-liquid separation device, wherein the mixture is a used adsorbent used in water treatment. In the solid-liquid separator of Claim 1 or Claim 2,
A solid-liquid separation device, wherein the mixture is used activated carbon used in water treatment. In the solid-liquid separator of Claim 1 or Claim 2,
The sprayer is a horizontally installed pipe,
Connect to the upstream flow path with a connecting pipe that is rotatable at the top of the pipe center of gravity,
The pipe is provided with at least two spouts,
The spout is installed at a point-symmetrical position with the connecting pipe as a central axis;
The sprayer is rotated by the fluid force of the fluid discharged from the jetting port, with the jetting port being substantially perpendicular to the pipe and in a position between vertically downward and horizontal. Solid-liquid separator.