JP3473339B2 - Solvent regeneration apparatus and solvent regeneration method - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a solvent recycling apparatus and a solvent recycling method for separating a contaminated solvent contaminated by being used in a washing machine or the like into a clean solvent and a contaminant.

[0002]

2. Description of the Related Art A cleaning machine using a solvent is widely used as a means for removing contaminants such as oil adhering to articles. In the above washing machine, the solvent is brought into contact with the article,
Cleaning of an article is carried out by taking in contaminants adhering to the article into a solvent. Therefore, the solvent is gradually contaminated and becomes a contaminated solvent. Then, the contaminated solvent needs to be regularly regenerated to keep it clean.

Conventionally, the following devices and methods have been known as a device and a method for recycling the contaminated solvent. One is a batch distillation evaporation tank system in which a contaminated solvent is stored in a tank or the like and heated to a temperature higher than the evaporation temperature of the solvent to be regenerated, and the solvent vaporized thereby is cooled and condensed to be recovered (Japanese Patent Laid-Open Publication No. HEI-6 (1994)).
-182104).

One is a thin film evaporation method in which a contaminated solvent is spread in a thin film on the heat transfer wall surface, where only the solvent is vaporized and the vaporized solvent is recovered (Japanese Patent Laid-Open No. 51-337).
No. 3). Further, one is a flash evaporation method in which a contaminated solvent is sprayed onto a plate fin type heat exchanger or the like in an atomized state to vaporize and recover the solvent (JP-A-5-337302).

Further, a regenerating apparatus and method of a vacuum distillation system as shown below are also known (Japanese Patent Laid-Open No. 59-1202).
No. 02). That is, the contaminated solvent is sucked by a pump and sent to a heat exchanger consisting of a pipe spirally arranged on the outer circumference of the decompression tank. Then, the contaminated solvent is sprayed into the vacuum tank.

In the decompression tank, there is provided a separation plate arranged so as to overlap from the side wall of the decompression tank toward the center of the tank, and the sprayed contaminated solvent is separated into vaporized solvent and contaminants. To be separated. The vaporized solvent thus obtained is discharged from the vacuum tank and liquefied in the condenser. As a result, the clean solvent can be recovered. In this method, the structure of the reproducing device is relatively simple.

[0007]

However, the above-mentioned conventional vacuum distillation system has the following problems. That is, in the above method, when the boiling point of the solvent is high and the temperature is close to the boiling point of the contaminant, both the solvent and the contaminant vaporize,
It is difficult to separate the two. Therefore, it is difficult to efficiently regenerate the solvent. Further, the separation plate may hinder the recovery of the vaporized solvent.

In view of the above problems, the present invention is capable of efficiently regenerating a solvent having a high boiling point or a boiling point close to that of a contaminant, and a solvent regenerating apparatus having a simple apparatus structure. And a method for regenerating a solvent.

[0009]

According to a first aspect of the present invention, there is provided a solvent recycling apparatus for separating a pollutant-containing pollutant solvent into a clean solvent and a pollutant. Heating means for heating the contaminated solvent; ejection means for ejecting the pressurized and heated contaminated solvent in a decompression tank in a decompressed state in a spray form; and a tank heating means for heating the bottom and side walls of the decompression tank. By introducing and cooling the vaporized solvent that has been vaporized and separated in the vacuum tank,
It has a condensing means for liquefying the vaporized solvent and a discharging means for discharging the pollutant from the decompression tank to a pollutant receiver, and is further heated by a heating means for heating the pressurized pollutant solvent. temperature of contaminated solvent, Ri hot der than ambient temperature of the vacuum tank which is heated by the tank heater and tank heating means of the vacuum tank
Separates the bottom temperature and side wall temperature of the vacuum tank
A solvent regenerator characterized in that the temperature can be controlled .

The above-mentioned contaminated solvent means a solvent contaminated by the contaminants because it is used in a washing machine for removing contaminants such as oil adhering to articles. Examples of the solvent include low boiling point solvents such as trichloroethane and freon, and high boiling point solvents such as petroleum hydrocarbon solvents. Then, in the solvent regenerating apparatus according to the present invention, it is possible to regenerate the solvent contaminated with contaminants such as various cutting oils, processing oils and quenching oils.

As the pressurizing means, various ordinary pumps can be mentioned. Examples of the heating means and the tank heating means include heating by steam or heating by an electric heater.

Further, the tank heating means for heating the vacuum tank, you temperature capable of controlling the side wall and bottom separately of the vacuum tank. As a result, the temperature of the bottom is higher than that of the side wall, and the solvent remaining in the contaminant can be separated as the vaporized solvent. Therefore, the solvent regeneration efficiency can be further increased.

The side wall of the decompression tank has a temperature of 100.
It is preferable that the temperature of the bottom is heated to 110 ° C. As a result, it is possible to improve the quality and efficiency of the contaminated solvent at the same time. The contaminated solvent is transferred to the vacuum tank in a liquid state. Further, as the ejection means, means using various nozzles can be cited.

The operation of the present invention will be described below. A solvent regenerator according to the present invention comprises a pressurizing means and a heating means,
It is composed of a tank heating means, a condensing means, and a discharging means provided separately from the decompression tank and the heating means.

Therefore, the solvent in the contaminated solvent becomes a gaseous vaporized solvent and is jetted into the decompression tank. Also,
The contaminants in the contaminated solvent become droplets and are ejected into the decompression tank. Then, the atomized pollutant solvent hits the side wall of the decompression tank, but as a result, the contaminants in the liquid droplets drop to the bottom of the decompression tank. In addition, the vaporized solvent will drift in the vacuum tank as it is. As described above, the contaminants can be efficiently separated from the contaminated solvent.

Further, in the present invention, the heating means for heating the contaminated solvent and the tank heating means for heating the decompression tank are separately provided. Therefore, even when the boiling points of the solvent and the contaminant are close to each other, the temperature can be easily controlled, and the solvent can be efficiently regenerated.

The apparatus of the present invention can be constructed by relatively combining heating means, pressurizing means and the like. For this reason, the structure is simple, and the manufacturing cost and the operating cost can be reduced. Further, it has a structure capable of continuously regenerating the solvent, so that the solvent can be regenerated efficiently.

As described above, according to the present invention, it is possible to efficiently regenerate, for example, a solvent having a high boiling point or a boiling point close to that of a pollutant, and the solvent regeneration having a simple apparatus structure. A device can be provided.

Next, as in the invention of claim 2, the sprayed pollutant solvent is brought into contact with the inside of the decompression tank to separate the pollutant from the vaporized solvent and evaporate the pollutant solvent. It is preferable that a heating separation plate for accelerating the heating is provided, and that the heating separation plate is the inner wall surface itself of the side wall of the decompression tank against which the sprayed contaminated solvent is hit. This makes it possible to more efficiently separate the contaminant and the vaporized solvent. Further, since the heating separation plate is installed upright, the recovery of the vaporized solvent is not hindered.

Next, as in the third aspect of the present invention, the sprayed pollutant solvent is brought into contact with the inside of the decompression tank to separate the pollutant from the vaporized solvent and evaporate the pollutant solvent. It is preferable to dispose a heating separation plate for promoting the above, and the heating separation plate is erected inside the side wall of the decompression tank so that the spray-like contaminated solvent hits the inner surface thereof. . As a result, similarly to the second aspect, the contaminant and the vaporized solvent can be separated more efficiently.

Next, according to the invention of claim 4, the temperature of the contaminated solvent heated by the heating means is 110 to 120.
It is preferable that the temperature of the atmosphere is 100 ° C. and the atmospheric temperature of the decompression tank heated by the tank heating means is 100 to 110 ° C.

This makes it possible to improve the regenerating quality of the contaminated solvent and at the same time improve the regenerating efficiency.
If the temperature of the contaminated solvent is lower than 110 ° C, the regeneration efficiency may decrease. On the other hand, 120 ° C
If it exceeds the limit, the reproduction quality may deteriorate.
Further, if the atmospheric temperature of the decompression tank is lower than 100 ° C., the regeneration efficiency may decrease. on the other hand,
If the temperature exceeds 110 ° C, the reproduction quality may deteriorate.

Next, as in the fifth aspect of the present invention, it is preferable that the decompression tank has a cylindrical shape or a polygonal cylindrical shape.
As a result, the temperature of the side wall of the decompression tank can be stabilized, and the quality and efficiency of solvent regeneration can be improved.

Further, the invention of claim 6 is a method for regenerating a pollutant containing a pollutant into a clean solvent and a pollutant, wherein the pollutant is pressurized by a pressurizing means,
Then, the contaminated solvent heated by the heating means is sprayed into the decompression tank heated under pressure and heated by the decompression tank heating means, and the contaminated solvent heated under pressure is heated. The temperature of the contaminated solvent heated by the heating means is higher than the ambient temperature of the decompression tank heated by the tank heating means,
Moreover, the tank heating means of the depressurization tank is configured such that
The temperature of the bottom and the temperature of the sidewall can be controlled separately.
Yes constitutes, the atomized contaminated solvent into contact with the side wall of the vacuum tank, and a vaporized solvent and the contaminants were flashed off, then liquefied by condensation means the vaporized solvent, clean solvent and without Further, in the solvent regeneration method, the above-mentioned contaminants are discharged to a contaminant receiver by a discharge means.

As a result, as described in claim 1, the contaminant can be efficiently separated from the contaminant solvent. Also, heating means for heating the contaminated solvent,
Since the tank heating means for heating the decompression tank is separately provided, the temperature can be easily controlled even when the boiling points of the solvent and the contaminants are close to each other, so that the solvent can be efficiently regenerated.

Next, according to the invention of claim 7, the temperature of the contaminated solvent heated by the heating means is 110 to 120.
It is preferable that the temperature of the atmosphere is 100 ° C. and the atmospheric temperature of the decompression tank heated by the tank heating means is 100 to 110 ° C. As a result, similarly to the fourth aspect, it is possible to enhance the regeneration quality of the contaminated solvent and at the same time enhance the regeneration efficiency.

[0027]

DETAILED DESCRIPTION OF THE INVENTION

Embodiment Example A solvent regenerator according to an embodiment of the present invention and a solvent regenerating method using the same will be described with reference to FIG. It should be noted that the contaminated solvent according to the present example means that oil, which is a contaminant, is 5
It is a solvent contained by weight%. The above oils are general processing oils.

This example is a solvent regenerator 1 for separating a contaminated solvent 29 into a clean solvent 2 and a contaminant 202. First, the outline of the apparatus will be described. As shown in FIG. 1, the solvent regeneration apparatus 1 includes a pressurizing means 11 for pressurizing the contaminated solvent 29 and a heating means 12 for heating the pressurized contaminated solvent 29. Have. In addition, a jetting means 139 for jetting the pressurized and heated pollutant solvent 29 into the depressurized tank 13 in a depressurized state, and a tank heating means 14 for heating the bottom 131 and the side wall 132 of the depressurized tank 13.
1, 142.

Further, by introducing and cooling the vaporized solvent 201 evaporated and separated in the decompression tank 13, the condensing means 15 for liquefying the vaporized solvent 201 and the contaminant 202 from the decompression tank 13 are contaminated. And a discharging means for discharging to the receiver 138.

Further, the temperature of the contaminated solvent 29 heated by the heating means 12 is the same as that of the tank heating means 141, 14 described above.
The temperature is higher than the ambient temperature of the decompression tank 13 heated by 2.

Hereinafter, the reproducing apparatus 1 will be described in detail with reference to FIG. Pressurizing means 11 in the reproducing apparatus 1
Is a centrifugal pump. The heating means 12 is composed of a heater 120 and a heat exchanger installed so as to surround the heater 120. Steam 121, 122 is circulated in the heat exchanger, and the heat of the steam heats the contaminated solvent 29 in the heater 120.

Further, a pressure gauge 128 and a thermometer 129 are installed in a pipe connecting the heating means 12 and a decompression tank 13 which will be described later, and the pressurizing means 11 and the heating means are based on the detected values. 12 are controlled.

Next, the decompression tank 13 will be described. The decompression tank 13 has a substantially cylindrical shape and is provided with two tank heating means 141 and 142. One of the tank heating means 141 is provided for heating the bottom 131, and the other tank heating means 142 is provided for heating the side wall 132. The tank heating means 14
1,142 also steam 144,143,145,146
Is a heat exchanger that is distributed.

The ejection means 139 for the decompression tank 13 is a nozzle. Since the contaminated solvent 29 is pressurized, when it reaches the ejection means 139, it becomes the atomized contaminated solvent 20 and is ejected into the decompression tank 13. Then, the jetting means 139 is used for spraying the polluting solvent 2
It is arranged so that 0 hits the side wall 132. That is,
The side wall 132 of this example has a function as a heating separation plate.

Further, an outlet 130 for taking out the vaporized solvent 201 is provided above the decompression tank 13.
The bottom 131 of the decompression tank 13 is provided with a discharge port 139 for discharging the contaminant 202 that has fallen here. The discharge port 139 communicates with the contaminant receiver 138. Reference numeral 137 is a valve.

A pump 155 for maintaining the decompression tank 13 and the contaminant receiver 138 communicating with the decompression tank 13 in a decompressed state is connected via a pipe 156. The pump 155 also plays a role of introducing the vaporized solvent into the condensing means 15 as described later. The vaporized solvent 201 remaining in the contaminant receiver 138 is sent out to the sealed water tank 159 side through the pipe 156.

Condensing means 15 is connected to the outlet 130 of the decompression tank 13 via a pipe. The condensing means 15 includes a condenser 150 into which the vaporized solvent 201 is introduced and is condensed, and a heat exchanger for cooling the condenser 150. Cooling water 151, 15 is provided in the heat exchanger.
2 is in circulation.

From the decompression tank 13, vaporized solvent 2
A pump 155 is installed on the downstream side of the condensing means 15 so that 01 efficiently flows into the condensing means 15. Furthermore,
This pump 155 is used for the liquefied solvent 2 in the sealed water tank 159.
03, and also plays a role of decompressing the decompression tank 13 and the contaminant receiver 138.

A water sealing tank 159 for introducing the liquefied solvent 203 is provided on the downstream side of the condensing means 15. The sealed water tank 159 is also provided with a heat exchanger,
Cooling water 153 and 154 are circulated in the heat exchanger. In the sealed water tank 159, the liquefied solvent 20
No. 3 is cooled further to eliminate gas and become a complete liquid. Reference numeral 157 is a pipe through which the pump 155 circulates to perform liquid sealing.

Then, the contaminated solvent 29 is regenerated by using the solvent regenerator 1 as follows. First, as a pretreatment for applying the contaminated solvent 29 to the solvent regeneration device 1,
This is filtered to remove the contained solid contaminants.

Next, the contaminated solvent 29 is introduced into the solvent regenerator 1. The contaminated solvent 29 is pressurized by the pressurizing means 11 to a pressure of 1 kg / cm ² . Then, it is heated to 110 to 120 ° C. in the heater 120. Next, the pressurized and heated contaminated solvent 29 is ejected from the jetting means 1
At 39, it is jetted to the side wall 132 in the decompression tank 13. As a result, the contaminated solvent is sprayed into the contaminated solvent 20.
Becomes Then, the spray-like contaminated solvent 20 is the vaporized solvent 2
01 and droplet-like contaminants. The above decompression tank 1
The pressure in 3 is 50 Torr, and the temperature of the side wall 132 is 100.
C., the temperature of the bottom 131 is 110.degree.

The following phenomenon occurs in the decompression tank 13, and the vaporized solvent 201 and the contaminant 202 are separated. First, the droplet-shaped contaminant 202 hits the side wall 132, and drips and drops below the decompression tank 13 as it is. The contaminants 202 accumulated on the bottom 131 in this manner
Is discharged from the discharge port 139 to the contaminant receiver 138. The discharging means in this example is the discharging port 139 and the valve 137.

Further, in this example, since the temperature of the bottom portion 131 is different from the temperature of the side wall 132, the solvent still remaining in the contaminant 202 dropped on the bottom portion 131 is vaporized in the bottom portion 131. Becomes Then, the vaporized solvent 201 is led out of the decompression tank 13 through an outlet 130 provided in the upper portion of the decompression tank 13.

The vaporized solvent 201 is transferred to the condenser 150 in the condensing means 15 and is liquefied therein. This liquefied and clean solvent 203 is introduced into the sealing water tank 159 this time. Here, the solvent 203 is further cooled and is in a state without a gas body. In the above, contaminated solvent 2
Solvent 2 that is cleaner than 9 is regenerated.

Next, the function and effect of this example will be described. The solvent regenerator 1 in this example is composed of a pressurizing means 11, a heating means 12, a decompression tank 13, a tank heating means 141 provided separately from the heating means 12, a condensing means 15, and a discharging means.

Therefore, the solvent in the contaminated solvent 29 becomes the gaseous vaporized solvent 201 and is ejected into the decompression tank 13. Further, the contaminant 202 in the contaminated solvent 29 becomes droplets and is ejected into the decompression tank 13. Then, the sprayed pollutant solvent 202 hits the side wall 132, but by this, the pollutant 202 falls down to the lower portion of the decompression tank 13. In addition, the vaporized solvent 201 is used as it is in the decompression tank 1.
It will drift within 3. As described above, the contaminant 202 and the solvent 2 can be efficiently separated.

Further, in this embodiment, the heating means 11 for heating the contaminated solvent 29 and the tank heating means 141, 142 for heating the decompression tank 13 are separately provided. For this reason, particularly when the boiling points of the solvent 2 and the contaminant 202 are close to each other, it is easy to control the temperature.
Can be played.

Further, the apparatus of this example can be constructed by relatively combining heating means, pressurizing means and the like. For this reason, the structure is simple, and the manufacturing cost and the operating cost can be reduced. In addition, it is efficient because the solvent can be continuously regenerated.

Therefore, according to this example, it is possible to efficiently regenerate a solvent having a high boiling point or a boiling point close to that of a contaminant, and to provide a solvent regenerating apparatus and a solvent regenerating method having a simple apparatus structure. be able to.

In the solvent regenerator 1 according to the present embodiment, the sprayed pollutant solvent 20 is brought into contact with the inside of the decompression tank 13 to separate the contaminant 202 from the vaporized solvent 201 and contaminate them. A heating separation plate for promoting evaporation of the solvent 20 may be separately provided. In this case, the heating separation plate is erected inside the side wall 132 of the decompression tank 13 so that the sprayed contaminated solvent 20 hits the inner surface thereof. Thereby, the contaminant 202 and the vaporized solvent 201 can be separated more efficiently.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a structure of a solvent recycling apparatus according to an embodiment.

[Explanation of symbols]

1. ． ． Solvent recycling equipment, 11. ． ． Pressurizing means, 12. ． ． Heating means, 13. ． ． Decompression tank, 131. ． ． bottom, 132. ． ． Side wall, 138. ． ． Pollutant receiver, 139. ． ． Ejection means, 15. ． ． Condensing means, 201. ． ． Vaporization solvent, 202. ． ． Pollutant, 2. ． ． solvent, 201. ． ． Vaporization solvent, 202. ． ． Pollutant, 29. ． ． Contaminated solvent,

─────────────────────────────────────────────────── ─── Continuation of front page (56) References JP-A-7-80240 (JP, A) JP-A-59-120202 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) B01D 1/00-5/00

Claims (7)

(57) [Claims] 1. A solvent recycling apparatus for separating a pollutant-containing pollutant solvent into a clean solvent and a pollutant, a pressurizing means for pressurizing the pollutant solvent, and a heating means for heating the pressurized pollutant solvent. A jetting means for spraying the pressurized and heated contaminated solvent into a depressurized tank in a depressurized state, a tank heating means for heating the bottom and side walls of the depressurized tank, and evaporation in the depressurized tank. by cooling by introducing the separated vaporized solvent, and condensing means for liquefying the vaporized solvent, it has a discharge means for discharging the contaminants from said vacuum tank contaminants receiver, further the pressure The temperature of the contaminated solvent heated by the heating means for heating the pressurized contaminated solvent is higher than the ambient temperature of the decompression tank heated by the tank heating means.
And the tank heating means of the decompression tank is
The temperature of the bottom and the temperature of the sidewall can be controlled separately.
A solvent regeneration device characterized by being configured . 2. The decompression tank according to claim 1, wherein the sprayed polluted contaminated solvent is brought into contact with the decompressed tank to separate the contaminated substance from the vaporized solvent to promote evaporation of the contaminated solvent. A solvent regeneration device comprising a heating separation plate, wherein the heating separation plate is the inner wall surface itself of the side wall of the decompression tank against which the spray-like contaminated solvent hits. 3. The decompression tank according to claim 1, wherein the jetted spray-type contaminated solvent is contacted to separate the contaminated substance from the vaporized solvent to promote evaporation of the contaminated solvent. A solvent regenerator comprising a heating separation plate, and the heating separation plate is erected inside the side wall of the decompression tank so that the sprayed contaminated solvent hits the inner surface thereof. . 4. The method according to claim 1, wherein
The temperature of the contaminated solvent heated by the heating means is 110
The solvent regenerator is characterized in that the atmospheric pressure of the decompression tank heated by the tank heating means is 100-110 ° C. 5. The method according to any one of claims 1 to 4,
The solvent regeneration device, wherein the decompression tank has a cylindrical shape or a polygonal cylinder shape. 6. A clean solvent for a contaminated solvent containing a contaminant.
In the solvent regeneration method that separates into The contaminated solvent is pressurized by the pressure means, and then the heating means
Heated by Is the above-mentioned pressurized and heated contaminated solvent under reduced pressure?
In the decompression tank heated by the decompression tank heating means
It is sprayed in the form of a spray andAdd pressurized contaminated solvent
heatThe temperature of the contaminated solvent heated by the heating means is
Atmosphere of decompression tank heated by tank heating means
Higher than temperature,Moreover, the tank heating means of the depressurization tank is constructed by
The temperature of the bottom of the tank and the temperature of the sidewall can be controlled separately.
Configured to Do not contact the side wall of the vacuum tank with the atomized contaminated solvent.
And evaporate and separate the above contaminants and the vaporized solvent, After that, the vaporized solvent is liquefied by a condensing means to clean it.
Without solvent, Further, the above-mentioned pollutant is discharged to the pollutant receiver by the discharging means.
A method for regenerating a solvent, which is characterized in that 7. The temperature of the contaminated solvent heated by the heating means according to claim 6, is 110 to 120 ° C.,
The atmosphere temperature of the decompression tank heated by the tank heating means is 100 to 110 ° C, and the solvent regeneration method is characterized.