KR20170054123A - Spinning cone column including a foam eliminator - Google Patents

Abstract

Disclosed is an SCC including a foam remover. The SCC can reduce costs consumed in a process by physically removing foams generated in an SCC device without adding a separate material. The SCC including a foam remover comprises: a housing having a rotation axis in a length direction, having an inlet of a reactant including a volatile organic compound (VOC), and having an outlet of the reactant having the VOC removed therefrom, wherein the inlet and the outlet are formed at the top thereof; two or more fixing cones, each of which has a shape becoming narrower from the top end toward the bottom end thereof by having a predetermined slope, has an outer circumferential surface fixed to an inner wall of the housing around the rotation axis, has a central part having a hole and separated at a predetermined interval from the rotation axis, and is longitudinally disposed to enable the reactant to pass between the central part and the rotation axis; a rotation cone disposed at the bottom of each of the fixing cones, having a funnel shape disposed alternately with the fixing cones, having a central part coupled with the rotation axis, accommodating a reactant flowing down from the fixing cones, and rotating to supply the reactant to fixing cones disposed at the bottom thereof by means of centrifugal force; a first foam removing unit installed on the bottom surface of the rotation cone, having multiple pins installed therein to have keen ends, and removing foams generated therein during a process; and one or more second foam removing units coupled with any one end of the rotation axis, having multiple pins installed to have keen ends on a mesh-shaped inner frame, and removing foams which have not been removed by the first foam removing unit.

Description

SCC {SPINNING CONE COLUMN INCLUDING A FOAM ELIMINATOR}

The present invention relates to a SCC including a foam remover, and more particularly, to a method and apparatus for removing a foam generated inside a SCC apparatus without physically adding another material, , And a SCC that includes a foam remover.

Generally, the remaining monomer or solvent component remaining in the polymer produced by the chemical reaction is called VOC (volatile organic compounds). In order to remove the VOC from the polymer, a spinning cone column (SCC) . When the VOC is removed by using the SCC apparatus, it is common to set the operating pressure of the high vacuum. Especially, in the case of the emulsion polymer, a large amount of foam is generated in the SCC apparatus by the emulsifier in the product. The foam thus generated not only interferes with the flow of steam and vapor injected into the SCC device, but also causes deterioration of the separation efficiency and the drivability of the SCC. As a method for removing the current foam, a Centrifugal Defoamer (CDF) device for recovering foam from the upper part of the SCC is used. 1 is an SCC apparatus using a conventional CDF. As shown in FIG. 1, the SCF 4 is rotated at a very high speed while sucking the foam inside the SCC 4 at the CDF 2, And the foam existing inside the SCC 4 is removed. In addition, the method for removing the foam generated inside the SCC device is also known from several patents including injecting a defoamer or defoaming agent, There are many studies to remove foam.

Korean Patent Publication No. 10-2012-0132421 Korean Patent Publication No. 10-2013-0117723

As described above, a large amount of foam is generated inside the SCC device for removing the VOC in the polymer, and there is a method for removing the foam. However, since the CDF device can process only the foam recovered from the SCC, The foam generated inside the SCC apparatus can not be removed and only the operation ability of the SCC can be secured. Also, the method of using the defoaming agent also requires an additional process for recovering the defoamer, There is a problem that it is difficult to apply the antifoaming agent when it is desired to obtain a product of high purity because the antifoaming agent may affect the quality of the product.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a SCC including a foam remover that can physically remove foam generated inside the SCC device without adding any additional substance, thereby reducing the cost of the process will be.

In order to achieve the above object, the present invention provides a vacuum cleaner comprising: a housing having an axis of rotation in the longitudinal direction and having an inlet for a reactant containing a volatile organic compound (VOC) and an outlet for a reactant from which a VOC is removed; The outer circumferential surface is fixed to the inner wall of the housing and the central portion having a hole is spaced apart from the rotating shaft by a predetermined distance, Two or more stationary cones disposed vertically so that the reactant passes between the central portion and the rotation axis; A fixed cone positioned below the fixed cone and disposed in an intersecting relation with the fixed cone, the center portion being coupled to the rotating shaft to receive a reactant flowing down from the fixed cone, A rotary cone rotating to supply; A first foam remover installed on a lower surface of the rotary cone and provided with a plurality of sharp pins to remove foam generated in the process; And a plurality of sharp-edged fins provided at an inner skeleton of a mesh shape, which is coupled to either one end of the rotary shaft, and which removes the foam that has not been removed from the first foam removing unit, Rejection ". < / RTI >

According to the SCC including the foam remover according to the present invention, it is possible to physically remove the foam generated inside the SCC device without adding any additional substance, thereby reducing the cost required for the process.

Figure 1 is an SCC device using conventional CDF.
2 is a front view (A) of a SCC including a foam remover according to an embodiment of the present invention, an enlarged view (B) of a foam remover located inside the SCC, and a perspective view (C) of a foam remover .

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a front view (A) of a SCC including a foam remover according to an embodiment of the present invention, an enlarged view (B) of a foam remover located inside the SCC, and a perspective view (C) of a foam remover . Referring to FIG. 2, the SCC including the foam remover according to the present invention will be described. The SCC including the foam remover according to the present invention has a rotary shaft 10 in the longitudinal direction, and a volatile organic compound (VOC) (Polymer) reactant and an outlet for a reactant from which a VOC is removed. The housing 20 has a predetermined inclination and narrows from the upper end to the lower end. The outer circumferential surface A center portion having a hole formed therein is spaced apart from the rotary shaft 10 by a predetermined distance and is vertically disposed so as to allow the reactant to pass between the center portion and the rotary shaft A stationary cone 30 disposed at a lower portion of the stationary cone 30 and disposed at an intersection with the stationary cone 30, (Or a spinning cone) 40 that rotates to receive a reactant flowing down from the fixed cone 30 and then supply the reactant to the fixed cone 30 located at the bottom by a centrifugal force, A first foam remover 50 is provided on the lower surface of the rotary cone 40 and has a plurality of sharp pins to remove foams generated in the process. And a plurality of sharp pins 62 are provided on the inner skeleton of the mesh form and are connected to either one end of the rotary shaft 10, And one or more second foam removers 60 for removing foam that has not been removed.

The SCC including the foam remover according to the present invention may be applied to a conventional SCC apparatus for distilling or removing volatile compounds generated from a slurry or a liquid in a vacuum state, The description of the remaining components except for the foam removing units 50 and 60 of the present invention will be simplified or omitted.

The first foam remover 50 is installed on the lower surface of the rotary cone 40. When the rotary cone 40 is composed of two or more pieces, But may be appropriately installed, for example, one or three per two rotation cones 40, considering the amount of foam generated in the SCC. As shown in FIG. 2B, the first foam removing unit 50 is provided on both sides of the rotating shaft 10, that is, in a pair symmetrical to improve the flowability of the internal gas It is preferable to increase the flow rate of steam and steam discharged through the lower portion of the SCC device to the upper portion in order to move the VOC of the reactant upward, It is possible to freely install as much as it is capable of sufficiently removing the foam generated in the SCC.

The pins 52 constituting the first foam removing unit 50 are attached or coupled to the supporting member 54 of the first foam removing unit 50 provided on the lower surface of the rotary cone 40. [ Wherein the support member 54 is selected from the group consisting of pure metals such as iron and alloys such as stainless steel and the support member 54 is selected from the group consisting of welding, The pins 52 constituting the first foam removing unit 50 are installed on the lower surface of the rotary cone 40 by means of a method selected from the group consisting of welding, (54).

In addition, the material of the fins 52 constituting the first foam remover 50 does not cause damage such as corrosion due to reactants or steam supplied into the SCC device, As described above, it is possible to use any material that can be manufactured in a sharp shape as required to break the foam to be removed, and it may be different depending on the components of the reactant or vapor. Examples of the material include pure metals such as iron, stainless steel Alloys, plastics, wood, glass, and the like. Meanwhile, when the foam is removed using the first foam remover 50, the foam may adhere to the pin 52 of the first foam remover 50, and the removal of the foam may be insufficient The pin 52 of the first foam remover 50 may be coated with a Teflon, a Teflon, or a Teflon, for example, in order to prevent the material from being removed completely or removed even if the material is highly viscous. Ceramic, molybdenum and the like can be coated with a material having a low coefficient of friction and non-tacky property, and electro-polishing (EP) treatment is also possible.

The number of the fins 52 constituting the first foam remover 50 is preferably as large as possible, but may be increased or decreased according to the amount of foam generated in the SCC in consideration of cost, It is satisfactory if it is a number corresponding to a degree at which the generated foam can be sufficiently removed and is not particularly limited, but it is preferable that 1 to 5 pieces per 5 cm ² of the area of the first foam remover 50, It may be one per 1 cm ² of the area of the removal part 50.

The second foam removing unit 60 may be coupled to the rotary shaft 10 at any one end of the rotary shaft 10 but may be disposed on the fixed cone 30 and the rotary cone 40 And is preferably coupled to one end of the rotary shaft 10. That is, although the second foam removing unit 60 can be coupled to any one end of the rotary shaft 10, the foam that has not been removed by the first foam removing unit 50 can be removed more completely The rotary cone 40 may be located above the stationary cone 30 and the rotary cone 40 and more precisely on the rotary cone 40 where the first foam remover 50 is installed.

The second foam removing unit 60 may be attached or joined directly to one end (or one surface) of the rotary shaft 10, The first foam remover 50 and the second foam remover 60 are connected to the opposite ends of the support connection part 64 and the center of the support connection part 64 is connected to the rotary shaft 10 in the form of a wing, It is possible to remove the foam from the upper part of the SCC by moving the VOC of the reaction part upward, as in the case of the first foam removing part 50, It is preferable to fabricate and attach to the vanes as shown in Fig. 2 so as to increase the flow rate of steam and vapor discharged to the upper portion after being injected through the vanes.

As described above, the second foam removing unit 60 may be attached to or coupled to one end of the rotary shaft 10, but may be additionally attached to the other end of the rotary shaft 10 The combination can make the removal of the foam more complete, and can further increase the rising velocity of the vapor.

The second foam removing unit 60 has a skeleton structure 66 (for example, a plate having a mesh-like skeleton structure) inside the outer frame, and the mesh skeleton structure 66 A pin 62 is provided at a point where a line and a line meet. The material of the mesh skeleton structure 66 is such that the pin 62 can be attached or coupled without causing damage such as corrosion due to reactants or steam supplied into the SCC device, Metals and alloys such as stainless steel, and the like.

The support connection portion 64 is selected from the group consisting of pure metal such as iron and an alloy such as stainless steel and both ends of the support connection portion 64 are selected from the group consisting of welding, (60) and the central portion of the support connection (64) is engaged with the rotation shaft (10) by a method selected from the group consisting of welding, gluing, and physical bonding .

As described above, the fins 62 constituting the second foam remover 60 must be attached to or joined to the mesh framework 66, and may be attached by welding, by adhesion, The pin 62 may be attached to the mesh skeleton structure 66 in a state where the pin 62 is injected from the beginning into the mesh skeleton structure 66 instead of attaching or coupling the pin 62 to the manufactured mesh skeleton structure 66 You can also choose how to make it.

Like the fins 52 constituting the first foam remover 50, the material of the fins 62 constituting the second foam remover 60 is such that the reactant or steam supplied into the SCC apparatus As shown in Fig. 2 (C), it is possible to use any material that can be manufactured in a sharp shape, which is required to break the foam to be removed, without limitation, And examples thereof include pure metals such as iron, alloys such as stainless steel, plastics, wood, glass, and the like. On the other hand, when the foam is removed using the second foam remover 60, the foam may adhere to the pin 62 of the second foam remover 60 and the removal of the foam may be insufficient The pin 62 of the second foam removing unit 60 may be formed of Teflon, ceramic, or molybdenum (for example, The material having a non-tacky property can be coated. In addition, electro-polishing (EP) treatment is also possible.

The number of the pins 62 constituting the second foam remover 60 is preferably as large as the number of the pins 52 constituting the first foam remover 50. However, And the amount of foam generated in the SCC. It is satisfactory if there is a number corresponding to a degree that the generated foam can be sufficiently removed, and there is no particular limitation. However, 1 to 5 per unit area of 5 ㎝ ^2, preferably the first area may be one days per 1 ㎝ ² of the form, removing (50). Unlike the first foam removing unit 50, which is capable of subsequent removal through the second foam removing unit 60 even if the foam can not be completely removed, since the foam is generated in the lower part of the SCC and moves upward, It is preferable to install as many pins 62 as possible in the second foam removing unit 60 in which subsequent foam removal is not possible.

As described above, by using the SCC including the foam remover according to the present invention, the foam generated inside the SCC device can be used as a separate material (i.e., for chemically removing or physically removing the foam) It is possible to physically remove itself by the device installed in the SCC without adding the third substance, thereby reducing the cost of the process. Therefore, it is possible to completely replace the CDF apparatus which has conventionally been sucked in the SCC after the suction of the foam and then rotated at a high speed, and when the SCC including the foam remover according to the present invention is mixed with the CDF apparatus, By reducing the amount of foam to be processed in the apparatus, the load on the CDF apparatus can be reduced.

10:
20: Housing
30: Fixed cone
40: Rotating cone
50: First foam removal
60: Second foam removal

Claims (22)

A housing having a rotation axis in the longitudinal direction and having an injection port for a reactant containing a volatile organic compound (VOC) and an outlet for a reactant from which a VOC is removed;
The outer circumferential surface is fixed to the inner wall of the housing and the central portion having a hole is spaced apart from the rotating shaft by a predetermined distance, Two or more stationary cones disposed vertically so that the reactant passes between the central portion and the rotation axis;
A fixed cone positioned below the fixed cone and disposed in an intersecting relation with the fixed cone, the center portion being coupled to the rotating shaft to receive a reactant flowing down from the fixed cone, A rotary cone rotating to supply;
A first foam remover installed on a lower surface of the rotary cone and provided with a plurality of sharp pins to remove foam generated in the process; And
A plurality of pins having sharp ends are provided in a mesh-like inner skeleton to be coupled to any one end of the rotating shaft, and one or more second foam removing units, which remove the foam that has not been removed from the first foam removing unit, SCC comprising a form remover comprising: The SCC of claim 1, wherein the first foam remover is in the form of a pair of wings symmetrically centered about the axis of rotation. The SCC according to claim 1, wherein the fin constituting the first foam removing part is coated with a non-sticking material selected from the group consisting of Teflon, ceramic and molybdenum. The SCC as claimed in claim 1, wherein the second foam removing part is coupled to one end of a rotary shaft located above the stationary cone and the rotary cone. The foam remover as set forth in claim 1, wherein the second foam removing part is in the form of a wing that connects the two second foam removing parts to both ends of the supporting connection part and connects the central part of the supporting connecting part to the rotating shaft The SCC. The SCC of claim 5, wherein the support connection is selected from the group consisting of pure metals and alloys. 6. The SCC of claim 5, wherein both ends of the support connection are coupled with the second foam removal by a method selected from the group consisting of welding, gluing, and physical bonding. 6. The SCC of claim 5 wherein the central portion of the support connection engages the rotation axis by a method selected from the group consisting of welding, gluing, and physical coupling. The SCC according to claim 1, wherein the fin constituting the second foam removing part is coated with a non-sticking material selected from the group consisting of Teflon, ceramic and molybdenum. The SCC as claimed in claim 1, wherein the fins constituting the first foam removing part are attached or coupled to a supporting member of a first foam removing part provided on a lower surface of the rotary cone. 11. The SCC of claim 10, wherein the support member is selected from the group consisting of pure metals and alloys. 11. The SCC of claim 10, wherein the support member is mounted on the lower surface of the rotating cone by a method selected from the group consisting of welding, bonding and physical bonding. 11. The SCC of claim 10, wherein the fins forming the first foam remover are attached or coupled to the support member by a method selected from the group consisting of welding, bonding, and physical bonding. The SCC as claimed in claim 1, wherein the material of the fin constituting the first foam remover is selected from the group consisting of pure metal, alloy, plastic, wood and glass. The SCC as claimed in claim 1, wherein the number of fins constituting the first foam remover can be increased or decreased according to the amount of foam generated inside the SCC. The SCC of claim 1, wherein the number of fins forming the first foam remover is from 1 to 5 per 5 cm ² of the area of the first foam remover. The SCC as claimed in claim 1, wherein the fins constituting the second foam remover are provided at the points where the lines of the mesh skeleton structure meet. The SCC of claim 1, wherein the material of the mesh skeleton structure is selected from the group consisting of pure metals and alloys. The SCC according to claim 1, wherein the fins constituting the second foam remover are installed in the mesh skeleton by a method selected from the group consisting of welding, bonding and physical bonding. The SCC according to claim 1, wherein the material of the fin constituting the second foam removing part is selected from the group consisting of pure metal, alloy, plastic, wood and glass. The SCC as claimed in claim 1, wherein the number of fins constituting the second foam remover can be increased or decreased according to the amount of foam generated inside the SCC. The SCC as claimed in claim 1, wherein the number of fins constituting the second foam remover is 1 to 5 per 5 cm ² of the area of the ^second foam remover.

Images