JP5906684B2 - Synthetic rubber solution transfer method and synthetic rubber solution transfer device - Google Patents

Description

  The present invention relates to a means for transferring a high-viscosity synthetic rubber solution with less power.

  In the manufacturing process of the synthetic rubber product, the synthetic rubber solution is transferred using, for example, piping. The synthetic rubber solution often has a high viscosity.

  For example, a polybutadiene (butadiene rubber, BR) product is manufactured through the following process including solution polymerization (see pages 335 to 343 of Non-Patent Document 1). First, the butadiene monomer is purified, and the purified butadiene monomer is mixed with a solvent (solvent) such as toluene, and further, for example, a nickel-based catalyst is added and polymerized (in a polymerization vessel) to obtain a butadiene heavy polymer. A butadiene polymerization solution containing the coalesced is obtained. Thereafter, steam is applied (with a stripper) to remove the solvent from the butadiene polymerization solution (desolubilization, stripping), solid-liquid separation, dehydration, and drying to take out only the butadiene polymer. Further, it is molded into a predetermined shape to obtain a BR material (intermediate product). And if this intermediate product is processed, a synthetic rubber product (final product) such as a tire can be obtained. In such a production process, the butadiene polymerization solution from the polymerization step (polymerizer) to the desolubilization step (stripper) is an example of a high-viscosity synthetic rubber solution.

  Transfer of a high viscosity synthetic rubber solution produced through such a polymerization process by piping has been conventionally performed, but no prior literature suggesting improvements related to this transfer can be found. However, Patent Documents 1 and 2 can be confirmed regarding the transfer of sludge.

JP-A-1-105100 Japanese Patent Laying-Open No. 2005-320886

New polymer manufacturing process, written by Koji Saeki and Shinzo Omi, Industrial Research Co., Ltd., published on June 10, 1994

  When trying to transfer a high-viscosity synthetic rubber solution such as a butadiene polymerization solution, compared to a low-viscosity synthetic rubber solution, the pressure loss generated in the pipe used for transfer increases, and the synthetic rubber solution is applied to the inner wall of the pipe. Easy to adhere. Therefore, it is quite difficult to stably transport this high viscosity synthetic rubber solution. Even if it can be transferred, the power (operating cost) required for the transfer is increased, which is not preferable from the viewpoint of energy saving.

  On the other hand, measures such as increasing the inner diameter of the pipe or increasing the capacity of the transfer pump (lift, motor output) can be considered. However, increasing the capacity of the transfer pump contributes to stable transfer, but the power required for transfer is not reduced. On the other hand, if the inner diameter of the pipe is increased, the pressure loss during the transfer is reduced and the power is reduced, but the equipment cost for the production of a new synthetic rubber product is increased. Even if the existing facilities are used, the cost of improvement work increases. The problem that the equipment cost and the construction cost become high also occurs when the capacity of the transfer pump is increased.

  The present invention has been made in view of such circumstances, and the problem is that the pressure loss generated in the piping used for transfer does not increase (becomes small), and power required for transfer (operating cost). Is not excessively large (smaller), equipment cost and construction cost are not high (inexpensive), and a means for stably transferring a high viscosity synthetic rubber solution is provided. As a result of repeated research, it has been found that this problem can be solved by the following means, and the present invention has been completed.

  That is, first, according to the present invention, a high-viscosity synthetic rubber solution is transferred through a pipe, and a relatively low-viscosity liquid is moved to the vicinity of the inner surface of the pipe. A method of transferring a synthetic rubber solution to be injected is provided.

  In the synthetic rubber solution transfer method according to the present invention, the low-viscosity liquid is preferably a liquid used in the synthetic rubber production process.

  In the synthetic rubber solution transfer method according to the present invention, the low viscosity liquid is compatible with the synthetic rubber solution, and the high viscosity synthetic rubber solution is prepared through a polymerization step. The organic solvent used in the polymerization step is preferable. In this case, the organic solvent is preferably used after cooling. Furthermore, when the freezing point of the organic solvent is 0 ° C. or lower, the organic solvent is preferably cooled to 0 ° C. or lower.

  In the synthetic rubber solution transfer method according to the present invention, the high-viscosity synthetic rubber solution becomes a rubber material through a demelting process, and the low-viscosity liquid is vapor used in the demelting process. It is preferable that it is the same component as water.

  In the synthetic rubber solution transfer method according to the present invention, the synthetic rubber solution is butadiene rubber, isoprene rubber, styrene / butadiene rubber, styrene / isoprene rubber, ethylene / α-olefin copolymer rubber, ethylene / α-olefin / non-conjugated. When the polymerization solution contains a polymer selected from the group consisting of diene copolymer rubber, butyl rubber, styrene / butadiene / styrene block copolymers, and hydrogenated styrene / butadiene / styrene block copolymers, Used.

  Next, according to the present invention, a polymerization step of polymerizing a monomer mixed with a solvent to obtain a polymerization solution containing a polymer, a desorption step of removing a solvent from the polymerization solution by applying steam, ( From the solid-liquid mixture from which the solvent has been removed, a separation step of further separating the hot water from which the vapor has been liquefied to obtain a polymer, a dehydration step and a drying step of further removing the water of the polymer from which the hot water has been separated, And a method of producing a rubber material using any one of the synthetic rubber solution transfer methods described above as a transfer means for the polymerization solution, which has a forming step of forming the polymer from which moisture has been removed into a predetermined shape. Provided.

  Next, according to the present invention, a transfer pipe for transferring a high-viscosity synthetic rubber solution, one or more nozzles provided in the transfer pipe, and a high-viscosity synthetic rubber solution, There is provided a synthetic rubber solution transfer device having a storage tank for a relatively low viscosity liquid, a pipe for injection connecting the storage tank for the low viscosity liquid, and a nozzle.

  In the synthetic rubber solution transfer device according to the present invention, the transfer pipe connects a transfer source and a transfer destination of the high-viscosity synthetic rubber solution. Examples of the transfer source and the transfer destination include a storage tank (liquid tank), a polymerization reactor and other reactors, a reaction tower, a desolvator, and the like. Further, in the synthetic rubber solution transfer device according to the present invention, when pressure is required for transfer, a pump is provided (for example, at the transfer source). Although not limited, in the synthetic rubber solution transfer device according to the present invention applied to a mass production facility of synthetic rubber (rubber material), the size of the piping for transfer is about 4B (inch) to 12B, The size of the suitable piping for injection with respect to it is smaller than the piping size for transfer, and is about 1 / 8B to 2B.

  In the synthetic rubber solution transfer device according to the present invention, the low-viscosity liquid is preferably a liquid used in the synthetic rubber production process.

  In the synthetic rubber solution transfer device according to the present invention, the low-viscosity liquid is compatible with the synthetic rubber solution, and the high-viscosity synthetic rubber solution is prepared through a polymerization step, so that the low-viscosity liquid is The organic solvent used in the polymerization step is preferable. In this case, the organic solvent is preferably used after cooling. Furthermore, when the freezing point of the organic solvent is 0 ° C. or lower, the organic solvent is preferably cooled to 0 ° C. or lower.

  In the synthetic rubber solution transfer device according to the present invention, the high-viscosity synthetic rubber solution becomes a rubber material through a demelting process, and the low-viscosity liquid is vapor used in the demelting process. It is preferable that it is the same component as water.

  In the synthetic rubber solution transfer device according to the present invention, the synthetic rubber solution (to be transferred) is made of butadiene rubber, isoprene rubber, styrene / butadiene rubber, styrene / isoprene rubber, ethylene / α-olefin copolymer rubber, ethylene / α. -A polymerization solution containing a polymer selected from the group consisting of olefin / non-conjugated diene copolymer rubber, butyl rubber, styrene / butadiene / styrene block copolymer, and hydrogenated styrene / butadiene / styrene block copolymer. In some cases, it is preferably used.

  In the synthetic rubber solution transfer device according to the present invention, the nozzle is preferably capable of injecting a low-viscosity liquid from the outside of the pipe to the vicinity of the inner surface of the pipe.

  In the synthetic rubber solution transfer device according to the present invention, the nozzle can be installed in an arbitrary number at an arbitrary position in the transfer pipe. In order to prevent the low-viscosity liquid from mutually dissolving with the high-viscosity synthetic rubber solution immediately after the injection, the nozzle is desirably provided on the outlet side of the apparatus where stirring can occur. Examples of the apparatus in which stirring can occur include a polymerization apparatus (reactor, reaction tower), a transfer apparatus (pump, etc.), a mixing apparatus or a storage tank attached thereto.

  In the synthetic rubber solution transfer device according to the present invention, it is desirable that the nozzle is provided immediately before a portion where a large pressure loss occurs due to pipe resistance, such as a bent portion or a branch portion of the transfer pipe.

  In the synthetic rubber solution transfer device according to the present invention, at least one nozzle is required for each one of the transfer pipes. It is also possible to provide a plurality of nozzles at substantially the same location of the transfer pipe. In this case, for example, the length direction of the transfer pipe (the flow direction of the high viscosity synthetic rubber solution (fluid)) Even if the positions in the cross section perpendicular to are substantially the same, the position on the tube surface may be shifted by 45 °, 90 ° to 180 ° in the cross section, and a plurality of nozzles may be attached.

  In the synthetic rubber solution transfer device according to the present invention, the nozzle can be provided at right angles or obliquely with respect to the length direction of the transfer pipe. The right angle is when the angle formed by the length direction of the nozzle (the flow direction of the low-viscosity liquid (fluid)) and the length direction of the transfer pipe is 90 ° (see FIG. 2 described later). Inclined means that the angle formed between the length direction of the nozzle and the length direction of the transfer pipe is, for example, more than 0 ° to less than 90 ° and more than 90 ° with respect to the upstream side of the transfer nozzle mounting position. This is a case of less than ˜180 ° (see FIG. 3 described later as a case of 45 °).

  In the synthetic rubber solution transfer device according to the present invention, the nozzle injects a low-viscosity liquid between the inner wall of the transfer pipe and the high-viscosity synthetic rubber solution flowing in the transfer pipe. Provide to be able to. That is, it is desirable not to insert the tip of the nozzle deeply into the transfer pipe. If the injection is possible, the shape of the cross section perpendicular to the length direction of the nozzle may be a circle or an ellipse, but is not limited thereto.

  In the synthetic rubber solution transfer device according to the present invention and the synthetic rubber solution transfer device according to the present invention, if the synthetic rubber solution has a relatively high viscosity relative to a low viscosity liquid, the effects described later are exhibited. The viscosity of the preferred high viscosity synthetic rubber solution to which the synthetic rubber solution transfer device according to the present invention and the synthetic rubber solution transfer device according to the present invention are applied is about 7000-35000 CP (centipoise) as the viscosity at that temperature, The viscosity of the more preferable high viscosity synthetic rubber solution is about 15000 to 35000 CP.

  In the synthetic rubber solution transfer device according to the present invention and the synthetic rubber solution transfer device according to the present invention, if the low-viscosity liquid is relatively low in viscosity with respect to the high-viscosity synthetic rubber solution, the effects described later are exhibited. . The viscosity of the preferred low-viscosity liquid to which the synthetic rubber solution transfer device according to the present invention and the synthetic rubber solution transfer device according to the present invention are applied is the liquid used in the synthetic rubber manufacturing process. In this case, the viscosity of the low-viscosity liquid is about 0.700 to 1.700 CP (centipoise) at room temperature, and is about 0.500 to 1.700 CP (centipoise).

  In the synthetic rubber solution transfer device according to the present invention and the synthetic rubber solution transfer device according to the present invention, the injection of the low-viscosity liquid may be performed while controlling the amount to be a specific value. However, since the effect to be obtained is a slip effect (reduction in pressure loss), which will be described later, it is more possible to inject based on that while monitoring the pressure loss of the transfer pipe through which the high viscosity synthetic rubber solution flows preferable. Accordingly, in order to adjust the injection amount of the low-viscosity liquid, it is preferable to provide a low-viscosity liquid injection amount adjusting means in the vicinity of the nozzle. The injection amount adjusting means is, for example, a valve. A preferable low-viscosity liquid injection amount that provides a slip effect is about 50 to 2000 L / H.

  The synthetic rubber solution transfer device according to the present invention and the synthetic rubber solution transfer device according to the present invention are suitably used when the polymerization process included in the synthetic rubber production process is continuous polymerization. Continuous polymerization is a production system in which a polymerization solution and a rubber product are produced without interruption. In continuous polymerization, a polymerization apparatus is used so that a liquid (solution or the like) for the polymerization always flows in one or more polymerization apparatuses (reactors). In contrast, batch (batch) polymerization is a production method in which a polymerization solution and a rubber product are produced discontinuously. In batch polymerization, a polymerization liquid (solution, etc.) is temporarily stored in a polymerization vessel (reactor), and from charging to reaction is performed.

  The synthetic rubber solution referred to in this specification refers to a state (solution) in which synthetic rubber is dissolved in a solvent after the polymerization step (solution polymerization step) in the synthetic rubber production process. As the polymerization reaction proceeds, the viscosity of the synthetic rubber solution increases. Moreover, when the ratio of the solvent decreases, the viscosity of the synthetic rubber solution increases.

  The organic solvent referred to in the present specification refers to a solid, liquid, or liquid that dissolves gas, which is an organic substance. Originally, it should be called (organic) solvent, but industrially, it is often called (organic) solvent.

  The term “compatible” as used herein refers to a property in which two or more fluids dissolve each other.

  The pipe resistance referred to in this specification refers to resistance generated when a fluid flows in the pipe. In addition, the pressure loss (also referred to as pressure loss) in the present specification refers to a pressure that is reduced by a resistance generated when a fluid flows in a pipe.

  In the synthetic rubber solution transfer method according to the present invention, a relatively low viscosity liquid is injected into the vicinity of the inner surface of the pipe (for transfer) with respect to the high viscosity synthetic rubber solution. Then, a low-viscosity liquid is injected between the inner wall of the transfer pipe and the high-viscosity synthetic rubber solution flowing in the transfer pipe (in other words, injected as such). The high-viscosity synthetic rubber solution is smoothly transferred in the pipe, pressure loss generated in the pipe for transfer is reduced, and power (operating cost) required for transfer is reduced (referred to as a slip effect). . Therefore, it is not necessary to increase the inner diameter of the pipe or increase the capacity of a transfer device such as a transfer pump, and the equipment cost or construction cost for the device for transferring the synthetic rubber solution can be suppressed.

  The synthetic rubber solution transfer method according to the present invention is applicable to an apparatus for transferring a synthetic rubber solution in an existing synthetic rubber manufacturing facility. According to the synthetic rubber solution transfer method of the present invention, as described above, the pressure loss generated in the transfer pipe is reduced and the power required for the transfer is reduced, so that the transfer of the existing synthetic rubber solution is reduced. It is possible to transfer a larger amount, a higher viscosity, a larger amount and a higher viscosity of a synthetic rubber solution by a device that does not change the piping or transfer device (pump), etc. become. Therefore, it contributes to the increase in production of synthetic rubber using existing synthetic rubber manufacturing equipment.

  According to the method for transferring a synthetic rubber solution according to the present invention, adhesion of a gel substance to a pipe inner wall (for transfer) (this increases pipe resistance) is suppressed, and narrowing and blockage of a pipe flow path are suppressed. Is done. Therefore, it is possible to realize the stable transfer of the high viscosity synthetic rubber solution over a long period of time.

  In the synthetic rubber solution transfer method according to the present invention, in a preferred embodiment, the low-viscosity liquid is a liquid used in the synthetic rubber production process. Therefore, the synthetic rubber production process is not adversely affected, and the quality of synthetic rubber products such as tires as final products is not deteriorated.

  Specifically, for example, a high-viscosity synthetic rubber solution is produced through a polymerization process, and a low-viscosity liquid is an organic solvent used in the polymerization process and is compatible with the synthetic rubber solution. Is the case. In this case, since the organic solvent (low viscosity liquid) is originally used in the polymerization process, it does not adversely affect the synthetic rubber production process. And if an organic solvent (low-viscosity liquid) is inject | poured immediately after a superposition | polymerization process, it will be removed by a subsequent desolubilization process. Therefore, it is not necessary to provide a means for newly removing a low-viscosity liquid (organic solvent). The organic solvent (low-viscosity liquid) exhibits a slip effect on the high-viscosity synthetic rubber solution (polymerization solution) from the polymerization step to the desolubilization step.

  When an organic solvent is used as the low-viscosity liquid, if it is used after cooling, the compatibility with the high-viscosity synthetic rubber solution decreases, and the slip effect is more reliably exhibited. That is, since the two do not immediately melt, a low-viscosity liquid continues to exist in the form of a film between the inner wall of the transfer pipe and the high-viscosity synthetic rubber solution flowing in the transfer pipe. The slip effect is sustained. For example, when the freezing point of an organic solvent is 0 ° C. or lower and the organic solvent is cooled to 0 ° C. or lower and used, the compatibility is surely lowered, so that the slip effect is reliably maintained.

In addition, for example, a case where a high-viscosity synthetic rubber solution becomes a rubber material through a demelting step, and a low-viscosity liquid is water is exemplified. In this case, water (a low-viscosity liquid) is originally the same component as the vapor used in the demelting step, and therefore does not adversely affect the synthetic rubber production process. And if water (low viscosity liquid) is inject | poured before a demelting process, it will be removed by a subsequent (solid-liquid) separation process and a dehydration process. Therefore, there is no need to newly provide a means for removing the low viscosity liquid (water). In addition, the case where the low-viscosity liquid is water indicates that water is the same component (H ₂ O) as steam, and water does not need to be exactly the same component as steam. Moreover, although the water by which the steam used at the demelting process was cooled can be reused effectively, it is not necessary to do so. If reused, it will contribute to water saving and resource saving.

  In the synthetic rubber solution transfer method according to the present invention, the synthetic rubber solution is butadiene rubber, isoprene rubber, styrene / butadiene rubber, styrene / isoprene rubber, ethylene / α-olefin copolymer rubber, ethylene / α-olefin / non-conjugated diene. It is suitably used in the case of a polymerization solution containing a polymer selected from the group consisting of copolymer rubber, butyl rubber, styrene / butadiene / styrene block copolymers, and hydrogenated styrene / butadiene / styrene block copolymers. The That is, the synthetic rubber solution transfer method according to the present invention can be widely used in various synthetic rubber production processes.

  Since the method for producing a rubber material according to the present invention uses the synthetic rubber solution transfer method according to the present invention as the polymerization solution transfer means, the operating cost is reduced as described above. In addition, the production of synthetic rubber can be increased by utilizing existing synthetic rubber manufacturing equipment.

  The synthetic rubber solution transfer device according to the present invention is a device that can actually carry out the synthetic rubber solution transfer method according to the present invention, and the effect is recognized where a slip effect is obtained through its implementation.

It is a flowchart which shows a part of example of synthetic rubber manufacturing equipment including one Embodiment of the synthetic rubber solution transfer apparatus which concerns on this invention. FIG. 2 is a perspective view illustrating an embodiment of a synthetic rubber solution transfer device according to the present invention, corresponding to a circle A portion in FIG. 1. FIG. 2 is a perspective view showing an embodiment of the synthetic rubber solution transfer device according to the present invention, corresponding to a circled B portion in FIG. 1.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention should not be construed as being limited to these embodiments, and the knowledge of those skilled in the art can be obtained without departing from the scope of the present invention. Various changes, modifications and improvements can be made based on this. For example, the drawings show preferred embodiments of the present invention, but the present invention is not limited by the modes shown in the drawings or the information shown in the drawings. In practicing or verifying the present invention, means similar to or equivalent to those described in the present specification can be applied, but preferred means are those described below.

  First, with reference to FIGS. 1-3, an example of synthetic rubber manufacturing equipment and one Embodiment of the synthetic rubber solution transfer apparatus based on this invention contained in it are demonstrated. The example of FIG. 1 is a part of manufacturing equipment when the synthetic rubber is polybutadiene (butadiene rubber, BR) (the butadiene rubber manufacturing equipment or the entire manufacturing process is described on pages 335 to 343 of Non-Patent Document 1, See especially page 343). In addition, the arrow in FIGS. 1-3 has shown the flow direction of the fluid in piping.

  A synthetic rubber production facility 1 shown in FIG. 1 includes a polymerization vessel 11, a storage tank 12, a desoldering device 13, a storage tank 14, a monomer storage tank 15, an organic solvent storage tank 16, and a water storage tank 21. The front stage of the monomer storage tank 15 is a monomer purifier 17, and the rear stage of the storage tank 14 is a solid-liquid separator 19. The preceding stage of the organic solvent storage tank 16 is an organic solvent purifier 18.

  The polymerization vessel 11 (reactor) is a container for performing a synthetic rubber polymerization reaction. The polymerization vessel 11 that performs polymerization of butadiene rubber has a cooling mechanism 11a, and can cool from the outside of the container using, for example, ammonia as a refrigerant. The desolver 13 (stripper) removes and collects the organic solvent 3 (solvent) contained in the butadiene polymerization solution 4 (synthetic rubber solution) obtained by the polymerization by causing the vapor 54 supplied thereto to act. Container.

  The storage tank 12 and the storage tank 14 are buffer tanks (tanks). The storage tank 12 is a storage tank for temporarily storing the butadiene polymerization solution 4 that has undergone the polymerization reaction. The storage tank 12 can absorb the difference in the processing amount between the polymerization reaction process and the desolubilization (organic solvent removal recovery) process performed in the next desulfurizer 13. Further, when the composition of the butadiene polymerization solution 4 is disturbed, it can be stored temporarily or the physical properties can be made uniform by mixing. The storage tank 14 is a storage tank for temporarily storing the butadiene polymerization solution 4 that has been completely dissolved. The storage tank 14 can absorb the difference in processing amount between the demelting process and the solid-liquid separation process performed in the next solid-liquid separator (not shown).

  The polymerization vessel 11, the storage tank 12, the demelter 13, and the storage tank 14 include a mixing device. The mixing device includes, for example, an electric motor (M), a stirring blade (including a helical member (helical ribbon)), and a shaft that connects them. The mixing device of the polymerization vessel 11 mixes the catalyst 51 for the polymerization reaction, the butadiene monomer 2 and the organic solvent 3. The mixing device of the storage tank 12 mixes the butadiene polymerization solution 4 with the polymerization terminator 52 and the antiaging agent 53. The synthetic rubber manufacturing facility 1 is appropriately equipped with a transfer device (pump (P)). In the synthetic rubber production facility 1 for producing butadiene rubber, the butadiene monomer 2 and the organic solvent 3 are fed into the polymerization vessel 11 by a pump. There is no pump on the outlet side of the polymerization vessel 11, and it is sent to the storage tank 12 (buffer container) as it is.

  The synthetic rubber manufacturing facility 1 includes two synthetic rubber solution transfer devices according to the present invention. First, a transfer pipe 31 (a transfer pipe for transferring a high-viscosity synthetic rubber solution) connecting the polymerization vessel 11 and the storage tank 12, and one nozzle 41 provided in the transfer pipe 31; The organic solvent storage tank 16 (a storage tank for a liquid having a relatively low viscosity with respect to a high-viscosity synthetic rubber solution) and an injection pipe 32 that connects the organic solvent storage tank 16 and the nozzle 41 according to the present invention. One synthetic rubber solution transfer device is constructed. A valve is provided in the vicinity of the nozzle 41 (injection pipe 32 before entering the transfer pipe 31). With this valve, the injection amount of the low-viscosity liquid (organic solvent 3) can be adjusted.

  The organic solvent 3 is a low-viscosity liquid and is a liquid (solvent) used in the production process of butadiene rubber (synthetic rubber). The organic solvent storage tank 16 serves as a storage tank for the solvent (organic solvent 3) used in the polymerization process and a storage tank for the low-viscosity liquid (organic solvent 3). The nozzle 41 (for example) is attached to the transfer pipe 31 at an angle of 90 ° with respect to the transfer pipe 31 from the lower side (for example) when the transfer pipe 31 is installed approximately horizontally.

  Further, a transfer pipe 33 (a transfer pipe for transferring a high-viscosity synthetic rubber solution) connecting between the storage tank 12 and the desulfurizer 13, and two nozzles 42 provided in the transfer pipe 33, The water storage tank 21 (a storage tank for a liquid having a relatively low viscosity with respect to the high-viscosity synthetic rubber solution) and an injection pipe 34 connecting (branching) the water storage tank 21 and the (two) nozzles 42. Thus, another synthetic rubber solution transfer device according to the present invention is configured. A valve is provided in the vicinity of each of the nozzles 42 (injection pipe 34 before entering the transfer pipe 33). With this valve, it is possible to adjust the injection amount of the low-viscosity liquid (water 5).

  The butadiene polymerization solution 4 is a high-viscosity synthetic rubber solution that becomes a rubber material through a demelting process. The water 5 is a low-viscosity liquid and is the same component as the vapor 54 used in the demelting step (desolubilizer 13). Although the water 5 is sent to the water storage tank 21 (for example) from the water supply 20 and stored therein, the steam 54 used in the desulfurizer 13 may be cooled and stored as water 5 in the water storage tank 21 instead. . The two nozzles 42 are attached to the transfer pipe 31 at an angle of 45 ° with respect to the transfer pipe 33 (for example) from below (for example) when the transfer pipe 33 is installed substantially vertically (for example). . The positions of the two nozzles 42 are substantially the same in the cross section perpendicular to the length direction of the transfer pipe 33 (the flow direction of the butadiene polymerization solution 4), and in the cross section of the transfer pipe 33 (for example) It is shifted by 180 °.

  Next, a method for producing the synthetic rubber solution transfer device according to the present invention will be described by taking the above two synthetic rubber solution transfer devices included in the synthetic rubber production facility 1 as an example. The synthetic rubber solution transfer device according to the present invention can be obtained by purchasing or processing a commercially available member / pipe and assembling it. In addition to the case where the synthetic rubber manufacturing facility 1 is newly constructed, the synthetic rubber solution transfer device according to the present invention can be incorporated even if it is already installed and modified.

  As the transfer pipes 31, 33, carbon steel pipes (SGP, STPG (Japanese Industrial Standards)) and stainless steel pipes (SUS304, SUS316 (Japanese Industrial Standards)) can be suitably used. Carbon pipes (SGP, STPG, STPL (Japanese Industrial Standards), stainless steel pipes (SUS304, SUS316 (Japanese Industrial Standards)) can be suitably used as the injection pipes 32 and 34. Materials of the nozzles 41 and 42 For example, carbon steel pipes (SGP, STPG (Japanese Industrial Standards) and stainless steel pipes (SUS304, SUS316 (Japanese Industrial Standards) can be preferably used. Transfer pipes 31 and 33 and nozzles 41 and 42 are different from each other. It is preferable to use the same material to avoid metal welding.

  Next, the method for producing a rubber material according to the present invention will be described taking butadiene rubber as an example. In addition, through this description, the synthetic rubber solution transfer method according to the present invention will be described by taking as an example the case of using the synthetic rubber production facility 1 including the synthetic rubber solution device according to the present invention.

  The butadiene monomer 2 (1,3-butadiene) purified by the monomer purifier 17 (not shown) is stored in the monomer storage tank 15. The butadiene monomer 2 is generally produced by ethylene (as a by-product) by thermal decomposition of naphtha taken from crude oil. Further, the organic solvent 3 (toluene, benzene, xylene, etc.) purified by the organic solvent purifier 18 (not shown) is stored in the organic solvent storage tank 16. Then, the butadiene monomer 2, the organic solvent 3, and the catalyst 51 (nickel, titanium, cobalt, neodymium, lithium, etc.) are sent to the polymerizer 11, mixed, and polymerization (reaction) is carried out. Do. Then, a butadiene polymerization solution 4 (high viscosity synthetic rubber solution) containing a butadiene polymer is generated (polymerization step).

  Next, the butadiene polymerization solution 4 is sent to the storage tank 12 through the transfer pipe 31. At this time, separately from the polymerization (reaction), the organic solvent 3 having a relatively low viscosity with respect to the butadiene polymerization solution 4 is transferred from the organic solvent storage tank 16 through the injection pipe 32 and the nozzle 41 to the transfer pipe 31. Inject into the vicinity of the inner surface. If it does so, the low-viscosity organic solvent 3 will exist in the form of a film | membrane between the inner wall of the piping 31 for transfer, and the butadiene polymerization solution 4, and a slip effect will be expressed. Thereafter, in front of the storage tank 12, a polymerization terminator 52 (such as methanol) and an antiaging agent 53 are further injected and mixed.

  Next, the (stable) butadiene polymerization solution 4 is sent from the storage tank 12 to the desulfurizer 13 via the transfer pipe 33. At this time, water 5 having a relatively low viscosity with respect to the butadiene polymerization solution 4 is injected from the water storage tank 21 into the vicinity of the inner surface of the transfer pipe 33 through the injection pipe 34 and the nozzle 42. Then, the low-viscosity water 5 exists in the form of a film between the inner wall of the transfer pipe 33 and the butadiene polymerization solution 4, and a slip effect is exhibited. Thereafter, steam 54 at 105 to 200 ° C. is applied in the desolder 13. At this time, part of the water 5 also becomes steam. By this action, the excess organic solvent 3 (solvent, low-viscosity liquid) is removed from the butadiene polymerization solution 4 and recovered (desolubilization step).

  When the organic solvent 3 is removed, a solid-liquid mixture is obtained in which a crumb-like butadiene polymer is present in hot water in which the vapor 54 (including water 5) is liquefied. Thereafter, hot water is separated from the solid-liquid mixture to obtain a butadiene polymer (separation step). Then, the butadiene polymer is further dehydrated with a dehydrator (dehydration process), dried with a drying apparatus (drying process), (for example) formed into a predetermined block shape with a press molding apparatus, and necessary wrapping is performed. If applied, a rubber material (intermediate product) can be obtained.

  EXAMPLES Hereinafter, although this invention is demonstrated based on an Example, this invention is not limited at all by these Examples.

  (Example 1) In a butadiene rubber production facility similar to the synthetic rubber production facility 1 shown in FIG. 1, a butadiene polymerization solution is transferred at an arbitrary flow rate Q in a transfer pipe at the outlet of the polymerization vessel. It was. At this time, the pressure loss at the outlet of the polymerization vessel was 0.470 MPa (absolute pressure, the same in the following pressure loss).

  Then, in the same manner as in FIG. 2, a nozzle is provided at an angle of 90 ° with respect to the transfer pipe from below in the horizontal portion of the transfer pipe immediately after the outlet of the polymerization vessel. The organic solvent used in the polymerization step was injected at a flow rate of 300 L / H. At this time, the pressure loss at the outlet of the polymerization vessel was 0.441 MPa, and the pressure loss was reduced by 0.029 MPa as compared with that before injecting the organic solvent.

  (Example 2) The conditions before injection of the organic solvent are the same as those in Example 1. Then, unlike the embodiment of FIG. 2, a nozzle is provided at an angle of 90 ° with respect to the transfer pipe from above, and the nozzle is transferred from the nozzle to the transfer pipe. The organic solvent used in the polymerization step was injected at a flow rate of 300 L / H. At this time, the pressure loss at the outlet of the polymerization vessel was 0.440 MPa, and the pressure loss was reduced by 0.030 MPa in terms of gauge pressure as compared with before injecting the organic solvent.

  (Example 3) The conditions before injection of the organic solvent are the same as those in Example 1. And, unlike the embodiment of FIG. 2, a nozzle is provided at a 90 ° angle to the transfer pipe from the right side of the transfer direction in the horizontal direction of the transfer pipe immediately after the outlet of the polymerization vessel. The organic solvent used in the polymerization process was injected from the nozzle into the transfer pipe at a flow rate of 300 L / H. At this time, the pressure loss at the outlet of the polymerization vessel was 0.440 MPa, and the pressure loss was reduced by 0.030 MPa as compared with that before the organic solvent was injected.

  (Example 4) The conditions before injection of the organic solvent are the same as those in Example 1. Then, unlike the embodiment shown in FIG. 2, the butadiene polymerization solution is provided with a nozzle at an angle of 90 ° with respect to the transfer pipe from the left side with respect to the transfer direction in the horizontal portion of the transfer pipe immediately after the outlet of the polymerization vessel. The organic solvent used in the polymerization process was injected from the nozzle into the transfer pipe at a flow rate of 300 L / H. At this time, the pressure loss at the outlet of the polymerization vessel was 0.441 MPa, and the pressure loss was reduced by 0.029 MPa in terms of gauge pressure as compared with before injecting the organic solvent.

  Example 5 In the same butadiene rubber production facility as in Examples 1 to 4, the flow rate of the butadiene polymerization solution in the transfer pipe at the outlet of the polymerization vessel was adjusted to 1.05 times the flow rate Q. At this time, the pressure loss at the outlet of the polymerization vessel was 0.495 MPa. When the organic solvent used in the polymerization step was injected under the same conditions as in Example 1, the pressure loss at the outlet of the polymerization vessel was 0.465 MPa, and the pressure loss was less than the gauge before the organic solvent was injected. The pressure decreased by 0.030 MPa.

  (Example 6) In the same butadiene rubber production equipment as in Examples 1 to 4, the flow rate of the butadiene polymerization solution in the transfer pipe at the outlet of the polymerization vessel was adjusted to 1.1 times the flow rate Q. At this time, the pressure loss at the outlet of the polymerization vessel was 0.518 MPa. And when the organic solvent used for the polymerization step was injected under the same conditions as in Example 1, the pressure loss at the outlet of the polymerization vessel was 0.488 MPa, compared with the pressure loss before injecting the organic solvent, It decreased by 0.030 MPa.

  The synthetic rubber solution transfer method and the synthetic rubber solution transfer device according to the present invention are suitably used as means for transferring a synthetic rubber solution (polymerization solution) in the manufacturing process of various (synthetic) rubber products.

1: Synthetic rubber production equipment, 2: butadiene monomer, 3: organic solvent, 4: butadiene polymerization solution, 5: water, 11: polymerizer, 11a: cooling mechanism, 12: storage tank, 13: desolvator, 14: storage tank 15: Monomer storage tank, 16: Organic solvent storage tank, 17: Monomer purifier, 18: Organic solvent purifier, 19: Solid-liquid separator, 20: Water supply, 21: Water tank, 31: Pipe for transfer, 32: Injection Pipe: 33: transfer pipe, 34: injection pipe, 41: nozzle, 42: nozzle, 51: catalyst, 52: polymerization terminator, 53: anti-aging agent, 54: steam.

Claims (3)

A method of transferring a high viscosity synthetic rubber solution through a pipe,
While injecting a relatively low-viscosity liquid relative to the high-viscosity synthetic rubber solution into the vicinity of the inner surface of the pipe,
The low-viscosity liquid is a liquid used in the production process of the synthetic rubber, and is compatible with the synthetic rubber solution;
Synthetic rubber solution of the high viscosity, produced through the polymerization process, the low viscosity liquid, Ri organic solvent der used in that the polymerization step,
The viscosity of the synthetic rubber solution is 7000-35000 CP,
The freezing point of the organic solvent is not more 0 ℃ less, synthetic rubber solution transfer method Ru used to cool the organic solvent 0 ℃ below. The synthetic rubber solution is butadiene rubber, isoprene rubber, styrene / butadiene rubber, styrene / isoprene rubber, ethylene / α-olefin copolymer rubber, ethylene / α-olefin / non-conjugated diene copolymer rubber, butyl rubber, styrene / butadiene / The synthetic rubber solution transfer method according to claim 1, which is a polymerization solution containing a polymer selected from the group consisting of a styrene block copolymer and a hydrogenated styrene / butadiene / styrene block copolymer. A polymerization step of polymerizing a monomer mixed with a solvent to obtain a polymerization solution containing the polymer;
A desolubilization step of removing the solvent from the polymerization solution by applying steam;
Further, a separation step of separating the hot water in which the steam is liquefied to obtain a polymer,
A dehydration step and a drying step for further removing water from the polymer from which the hot water has been separated,
And a molding step of molding the polymer from which the moisture has been removed into a predetermined shape,
Have
The manufacturing method of the rubber raw material which uses the synthetic rubber solution transfer method of Claim 1 or 2 as a transfer means of the said polymerization solution.

Images