JP2011245694A - Device for supplying of liquefied carbon dioxide, and apparatus for manufacturing of polyurethane foam with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquefied carbon dioxide supply device having a compact and low cost configuration in which liquefied carbon dioxide can be cooled efficiently and vaporization can be prevented.SOLUTION: The liquefied carbon dioxide supply device 2 includes a piston pump-type measuring pump 11 having a metal cylinder 23 in which a first pressure chamber 24 of an upstream side and a second pressure chamber 25 of a downstream side are formed, and supplies the liquefied carbon dioxide. The device includes a temperature regulator (cooling section 12) carrying out temperature control of the section forming the first pressure chamber in the metal cylinder. Preferably, the cooler has a Peltier element 58.

Description

  The present invention relates to a liquefied carbon dioxide supply device and a polyurethane foam manufacturing apparatus having the liquefied carbon dioxide supply device. More specifically, the present invention relates to a liquefied carbon dioxide supply having a small and inexpensive configuration capable of efficiently controlling the temperature of liquefied carbon dioxide to prevent vaporization. The present invention relates to an apparatus and a polyurethane foam manufacturing apparatus including the apparatus.

  Conventionally, polyurethane foam has been used in a wide range of fields, such as the formation of heat insulation boards, the formation of heat insulation walls at construction sites by the spraying method, and the formation of artificial embankments by the spraying method. This polyurethane foam usually uses a foam raw material containing a polyol component, a polyisocyanate component, and a foaming agent, and weighs and feeds each component to collide each component and stir, or After mixing, the mixture is made into a uniform mixture by a method such as stirring, and the mixture is discharged from a spray gun or the like, and the discharged foam material is foamed while reacting and solidifying.

  Although chlorofluorocarbon has been used as a foaming agent, the use of chlorofluorocarbon is restricted due to problems such as ozone layer destruction. Substituted chlorofluorocarbons used thereafter do not destroy the ozone layer, but have a problem that the global warming potential is extremely large. Therefore, water or carbon dioxide has been studied as a foaming agent for polyurethane foam. However, when only water is used as the foaming agent, a large amount of water must be used in order to sufficiently foam the polyurethane foam to obtain a lightweight foam with a low density. In this case, the foam may crack due to heat generated by the reaction between the polyisocyanate and water, and quality deterioration such as burning due to heat storage may occur. Further, when a large amount of water is used for weight reduction, an excessive urea bond is formed in the polyurethane foam, and the foam may become brittle. Moreover, when water is used as the foaming agent, the viscosity of the foam raw material is high, the polyol component and the polyisocyanate component are not sufficiently mixed, and the cell shape of the foam may become uneven.

  Furthermore, when carbon dioxide is used as a blowing agent, it is necessary to use liquefied carbon dioxide and measure it to supply a predetermined amount. However, since carbon dioxide has a low boiling point and is easily vaporized, When trying to pump by a metering pump from a container filled with liquefied carbon dioxide, vaporized carbon dioxide is likely to be mixed, and it may not be possible to pump quantitatively. Therefore, in order to suppress such vaporization of liquefied carbon dioxide, a liquefied carbon dioxide quantitative supply device including a cooling means for cooling the liquefied carbon dioxide flow path and the metering pump has been proposed (for example, Patent Document 1). And 2).

JP 2003-82050 A JP 2006-29895 A

  However, since the devices of Patent Documents 1 and 2 employ a chiller and a heat exchanger having a relatively large and expensive structure as a cooling means, it is necessary to secure a sufficient place at the construction site. . In addition, if the chiller and the heat exchanger are separated from each other, a heat loss in which the refrigerant temperature rises due to the ambient temperature is generated in the pipe line for transferring the refrigerant cooled by the chiller to the heat exchanger, and the cooling is sufficiently performed. May not be done.

  Here, piston pumps are classified as positive displacement pumps. In general, positive displacement pumps have good quantitativeness and can obtain a relatively high pressure, that is, a high head. In order to respond to high-rise buildings in the construction of sprayed rigid urethane foam, a high lift is required as a foaming machine equipped with a pump for transferring the urethane foam raw material, and the mixing ratio of the isocyanate component and polyol component of the urethane foam raw material is In order to maintain, it is common to use a piston type pump with good quantitativeness. In addition, the piston pump is small, simple in structure, and easy to maintain compared to other positive displacement pumps and pumps other than positive displacement pumps. When the pump for transferring liquefied carbon dioxide (metering pump) and the pump for transferring urethane foam raw material are the same type of piston pump, the control signal is used to synchronize the reciprocating motion of the piston by sharing the signals for driving both pumps. By doing so, it becomes easy to ensure the quantitativeness of the mixing of the liquefied carbon dioxide. However, when a piston pump is adopted as a pump for transferring liquefied carbon dioxide, the pressure in the first pressure chamber on the upstream side is lowered during suction, and thus liquefied carbon dioxide may vaporize and cavitation may occur.

  The present invention has been made in view of the above situation, and a liquefied carbon dioxide supply device having a small and inexpensive configuration capable of preventing vaporization by efficiently adjusting the temperature of liquefied carbon dioxide and a polyurethane foam provided with the same. An object is to provide a manufacturing apparatus.

The present invention is as follows.
1. A liquefied carbon dioxide supply device for supplying liquefied carbon dioxide, comprising a piston pump type metering pump having a metal cylinder in which a first pressure chamber on the upstream side and a second pressure chamber on the downstream side are formed,
A liquefied carbon dioxide supply apparatus comprising temperature adjusting means for adjusting a temperature of a portion forming the first pressure chamber in the metal cylinder.
2. The temperature adjusting means has a Peltier element. The liquefied carbon dioxide supply device described.
3. The above-mentioned 1. further comprising a temperature sensor for detecting the temperature of the liquefied carbon dioxide. Or 2. The liquefied carbon dioxide supply device described in 1.
4). At least one of the pipe connected to the metering pump and the surface of the metering pump is coated with a discoloration paint that changes color due to a temperature change. To 3. The liquefied carbon dioxide supply device according to any one of the above.
5). Above 1. To 4. Liquefied carbon dioxide supply device according to any one of
A first container containing a first liquid mainly composed of polyisocyanate;
A second container containing a second liquid mainly composed of polyol,
A polyurethane obtained by mixing liquefied carbon dioxide as a blowing agent supplied from the liquefied carbon dioxide supply device, a first liquid supplied from the first container, and a second liquid supplied from the second container. An apparatus for producing polyurethane foam, characterized by producing foam.
6). The temperature adjusting means of the liquefied carbon dioxide supply device has a Peltier element, and the first liquid supplied from the first container and the second container supplied from the second container using waste heat of the Peltier element. 4. The above-described 5. further comprising a heating means for heating at least one of the two liquids. The polyurethane foam manufacturing apparatus as described.

According to the liquefied carbon dioxide supply device of the present invention, since the temperature adjusting means for adjusting the temperature of the portion forming the first pressure chamber in the metal cylinder is provided, the internal pressure tends to decrease when the liquefied carbon dioxide is sucked. The temperature of the liquefied carbon dioxide in the first pressure chamber can be efficiently controlled to prevent vaporization, and the temperature adjusting means and thus the entire apparatus can be configured to be small and inexpensive. As a result, liquefied carbon dioxide can be quantitatively and stably supplied to the foam raw material at the construction site and the like, and an excellent polyurethane foam having good construction and quality can be produced.
Further, when the temperature adjusting means has a Peltier element, the temperature adjusting means and thus the entire apparatus can be configured more compactly and inexpensively.
In addition, when a temperature sensor is further provided, the temperature of the liquefied carbon dioxide can be controlled because the temperature of the liquefied carbon dioxide is detected by the temperature sensor. In particular, when the temperature adjusting means is controlled based on the detection result of the temperature sensor, the temperature of the liquefied carbon dioxide can be adjusted more efficiently.
Furthermore, when a color-changing paint that changes color due to a temperature change is applied to at least one surface of the pipe connected to the metering pump and the metering pump, the temperature change of the liquefied carbon dioxide is caused by the color change of the color-changing paint. Since it can be grasped visually, temperature control of liquefied carbon dioxide can be performed.

According to the polyurethane foam manufacturing apparatus of the present invention, liquefied carbon dioxide as a blowing agent supplied from the liquefied carbon dioxide supply apparatus, the first liquid supplied from the first container, and the second liquid supplied from the second container. Are mixed to produce a polyurethane foam. In addition, since the liquefied carbon dioxide supply device is provided with temperature adjusting means for adjusting the temperature of the portion forming the first pressure chamber in the metal cylinder, the internal pressure tends to decrease when the liquefied carbon dioxide is sucked. The temperature of the liquefied carbon dioxide in the pressure chamber can be efficiently controlled to prevent vaporization, and the temperature control and thus the entire apparatus can be configured to be small and inexpensive. As a result, liquefied carbon dioxide can be quantitatively and stably supplied to the foam raw material at the construction site and the like, and an excellent polyurethane foam having good construction and quality can be produced. Furthermore, because the liquefied carbon dioxide supply device is configured with a piston pump metering pump, the piston pump is smaller and simpler in structure and maintenance than other positive displacement pumps and pumps other than positive displacement pumps. Is also easy. When the pump for transferring liquefied carbon dioxide (metering pump) and the pump for transferring urethane foam raw material are the same type of piston pump, the control signal is used to synchronize the reciprocating motion of the piston by sharing the signals for driving both pumps. By doing so, it becomes easy to ensure the quantitativeness of the mixing of the liquefied carbon dioxide.
Furthermore, when the temperature adjusting means of the liquefied carbon dioxide supply apparatus has a Peltier element and further includes a heating means, at least one liquid can be heated using waste heat of the Peltier element, thereby reducing energy loss. be able to.

The present invention will be further described in the following detailed description with reference to the drawings referred to, with reference to non-limiting examples of exemplary embodiments according to the present invention. Similar parts are shown throughout the several figures.
It is a schematic diagram which shows the outline of the polyurethane foam manufacturing apparatus which concerns on an Example. It is a top view of the metering pump which concerns on an Example. FIG. 3 is a view as seen from an arrow A in FIG. 2. It is operation | movement explanatory drawing of the said metering pump. It is operation | movement explanatory drawing of the said metering pump. It is operation | movement explanatory drawing of the said metering pump. It is operation | movement explanatory drawing of the said metering pump. It is operation | movement explanatory drawing of the said metering pump. It is operation | movement explanatory drawing of the said metering pump. It is a longitudinal cross-sectional view of the piping which concerns on an Example. It is a schematic diagram which shows the principal part of the polyurethane foam manufacturing apparatus of another form.

  The items shown here are exemplary and illustrative of the embodiments of the present invention, and are the most effective and easy-to-understand explanations of the principles and conceptual features of the present invention. It is stated for the purpose of providing what seems to be. In this respect, it is not intended to illustrate the structural details of the present invention beyond what is necessary for a fundamental understanding of the present invention. It will be clear to those skilled in the art how it is actually implemented.

1. Liquefied carbon dioxide supply apparatus Embodiment 1 The liquefied carbon dioxide supply apparatus according to the present invention includes a piston pump type metering pump (11) having a metal cylinder in which an upstream first pressure chamber and a downstream second pressure chamber are formed, and supplies liquefied carbon dioxide. The liquefied carbon dioxide supply device is characterized by comprising temperature adjusting means (12) for adjusting the temperature of a portion forming the first pressure chamber in the metal cylinder (see, for example, FIG. 2). In this liquefied carbon dioxide supply device, normally, liquefied carbon dioxide is sucked into the first pressure chamber from the outside of the metering pump, and liquefied carbon dioxide sucked into the first pressure chamber is sent to the second pressure chamber.

  Examples of the liquefied carbon dioxide supply device include a form in which the temperature adjusting means has a Peltier element (58) (for example, see FIG. 2 and the like). This Peltier element usually has a cooling plate that contacts or faces the outer surface of the portion forming the first pressure chamber in the metal cylinder.

  As the liquefied carbon dioxide supply device, for example, a form further including a temperature sensor (60) for detecting the temperature of the liquefied carbon dioxide can be mentioned (see, for example, FIGS. 2 and 3). This temperature sensor can be embedded, for example, in a portion forming the first pressure chamber in the metal cylinder. In the case of this form, for example, it is possible to further include a temperature controller (61) that controls the driving of the temperature adjusting means based on the detection result of the temperature sensor and sets the temperature of the liquefied carbon dioxide to a predetermined value or less (for example, (See FIG. 2 etc.) Thereby, the temperature control of the liquefied carbon dioxide whose temperature is adjusted by the temperature adjusting means can be carried out more accurately.

  As the liquefied carbon dioxide supply device, for example, (1) a form in which a discoloration paint (63) that changes color due to a temperature change of liquefied carbon dioxide flowing through the pipe is applied to the surface of the pipe connected to the metering pump ( For example, see FIG. 10 etc.), (2) One or a combination of two or more of the forms in which the surface of the metering pump is coated with a discoloration paint that changes color due to the temperature change of the liquefied carbon dioxide in the metering pump Can be mentioned. Examples of the discoloration paint include (a) a reversible type in which mercury iodide complex salt or the like is used as a pigment that changes color with the transition of the crystal form of the pigment compound used in the paint by heat. (B) The form which is an irreversible type | mold etc. by chemical changes, such as thermal decomposition reaction accompanied by a degassing etc. by the heating of the pigment mainly contained can be mentioned. The form (a) is preferred.

  Examples of the pipe in the form (1) include a pipe (19) for connecting a liquefied carbon dioxide pressurizing container and a metering pump to be described later, and at least one of a first liquid and a second liquid to be liquefied. Examples thereof include a pipe (43) for connecting a mixing unit (70) for mixing carbon dioxide and a metering pump (see, for example, FIG. 1). Moreover, the piping of said (1) form can be piping made from PTFE, for example. Thereby, compared with the case where steel piping is employ | adopted, since heat conductivity is low, the temperature rise of a liquefied carbon dioxide can be suppressed.

  As the liquefied carbon dioxide supply device, for example, the metering pump (11) includes a first piston portion (49) reciprocatingly moved in the first pressure chamber, and a reciprocating motion in the second pressure chamber connected to the first piston portion. And a second piston portion (50) that moves and has a smaller volume than the first piston portion (for example, approximately half the volume of the first piston portion) (for example, FIG. 2 and the like). reference). Thereby, liquefied carbon dioxide can be supplied quantitatively and more stably by the reciprocating movement of the first piston portion in the first pressure chamber and the reciprocating movement of the second piston portion in the second pressure chamber.

  Examples of the liquefied carbon dioxide supply device include a liquefied carbon dioxide container (8) for storing liquefied carbon dioxide, an inert gas container (9) for storing inert gas, and liquefied carbon dioxide from the liquefied carbon dioxide container. A liquefied carbon dioxide pressure vessel (10) having a lower inlet (10a) for injecting gas from below and an upper inlet (10b) for injecting inert gas from the inert gas container from above. ) And a metering pump (11) connected to the liquefied carbon dioxide pressure vessel (for example, see FIG. 1 and the like).

  As the liquefied carbon dioxide supply device, for example, the pressure difference between the liquefied carbon dioxide in the liquefied carbon dioxide pressure vessel and the gas phase part (inert gas or carbon dioxide (gas phase) or a mixture thereof) is measured. The form which further has a pressure difference measurement means (22) can be mentioned (for example, refer FIG. 1 etc.).

  As the liquefied carbon dioxide supply device, for example, the liquefied carbon dioxide pressure container has a lower supply port (10c) for supplying liquefied carbon dioxide pressurized in the container to the metering pump from below. (See, for example, FIG. 1 and the like). Thereby, the liquefied carbon dioxide which is not mixed with the inert gas can be reliably supplied to the metering pump.

2. Polyurethane foam manufacturing apparatus Embodiment 2 The polyurethane foam manufacturing apparatus according to the first embodiment is the same as in the first embodiment. Liquefied carbon dioxide supply device (2), a first container (3) containing a first liquid mainly composed of polyisocyanate, and a second container (4) containing a second liquid mainly composed of polyol. And mixing the liquefied carbon dioxide as the blowing agent supplied from the liquefied carbon dioxide supply device, the first liquid supplied from the first container, and the second liquid supplied from the second container. Thus, a polyurethane foam is produced (see, for example, FIG. 1). In addition, as the above-mentioned “main component ... liquid”, for example, when the liquid is 100% by mass, the lower limit of the total of the main component materials is 50% by mass or more (preferably 70% by mass or more, particularly 90% by mass or more). Moreover, the upper limit of the total of the materials as the main component is usually 99.9% by mass or less (preferably 99.8% by mass or less, particularly 99.4% by mass or less).

  As the polyurethane foam manufacturing apparatus, for example, the temperature adjusting means of the liquefied carbon dioxide supply apparatus has a Peltier element, and the first liquid and the second liquid supplied from the first container using the waste heat of the Peltier element. The form further provided with the heating means (72) which heats at least one liquid of the 2nd liquid supplied from a container can be mentioned (for example, refer FIG. 11 etc.). Examples of the heating means include a heater, a metal material having high thermal conductivity, a heat exchanger, and the like.

Here, the supply amount of the liquefied carbon dioxide used as the foaming agent in the production of the polyurethane foam can be adjusted according to the required foaming ratio and the use of the foam. The supply amount of the liquefied carbon dioxide can be 0.1 to 4.0% by mass when the total of the polyol component and the polyisocyanate component, that is, the total amount of the foam raw material is 100% by mass. It is preferable to set it as 0.2-2.3 mass%, especially 0.6-0.8 mass%. Thus, by using liquefied carbon dioxide as a foaming agent, the density of the foam can be reduced as compared with the case where only water that is often used as a foaming agent is used. That is, the expansion ratio can be increased. For example, when using only water, the density of the foam which is 40 to 90 kg / m ³ is combined with 0.1 to 4.0% by mass of liquefied carbon dioxide as the foaming agent with respect to the total amount of the foam raw material. 30 to 80 kg / m ³ .

Incidentally, liquefied carbon dioxide is usually used in combination with a blowing agent such as water, the density of the foam is 80 kg / ^{m 3} or more, in particular 100 to 200 kg / ^{m 3,} if you do not need high foaming, foam Only liquefied carbon dioxide can be used as an agent.

  In addition to polyol, polyisocyanate, and liquefied carbon dioxide, foaming agents other than liquefied carbon dioxide, catalysts, crosslinking agents, foam stabilizers, and the like can be added to the foam raw material. The polyol may be any of polyester polyol and polyether polyol, and various polyols can be used. A polymer polyol obtained by graft polymerization of a compound containing a vinyl group to a polyether polyol can also be used. Furthermore, polytetramethylene ether glycol, urea-dispersed polyether polyol, or the like can also be used. Of these polyols, polyether polyols to which alkylene oxide is added are preferred.

  A foaming agent, a catalyst, a crosslinking agent, a foam stabilizer, etc. may be blended in the polyol component or in the polyisocyanate component, but the foaming agent, catalyst and crosslinking agent are blended in the polyol component. In many cases, the foam stabilizer is blended in the polyisocyanate component. As the foaming agent, water is usually used. The amount of water added can be 0.5 to 8 parts by mass, particularly 3 to 6 parts by mass, when the polyol is 100 parts by mass.

  Moreover, a metal catalyst and an amine catalyst can be used as a catalyst. As the catalyst used at the construction site, an amine catalyst having a relatively fast reaction is often used, and an amine catalyst and a metal catalyst can be used in combination. Examples of the metal catalyst include stannous octoate, dibutyltin dilaurate, dibutyltin diacetate, and lead octenoate. The compounding amount of the metal catalyst can be 0.2 to 2 parts by mass when the polyol is 100 parts by mass. Only one metal catalyst may be used, or two or more metal catalysts may be used.

  Further, amine catalysts include triethylenediamine, triethylamine, N, N-dimethylcyclohexylamine, tetramethylethylenediamine, tetramethylpropane-1,3-diamine, tetramethylhexane-1,6-diamine, pentamethyldiethylenetriamine, tetramethyl. Examples include guanidine, N-methylmorpholine, dimethylmethylenediamine, and dimethylaminoethanol. The compounding quantity of this amine catalyst can be 0.5-25 mass parts, especially 2-18 mass parts, when a polyol is 100 mass parts. Only one type of amine catalyst may be used, or two or more types may be used.

  Moreover, as a crosslinking agent, diol, triol, tetraol, diamine, amino alcohol, etc. can be used. Examples of the diol include ethylene glycol, diethylene glycol, propylene glycol, dipropylene glycol, and 1,4-butanediol. Examples of the triol include glycerin and trimethylolpropane. Examples of tetraol include bentaerythritol. Furthermore, examples of the diamine include hexamethylene diamine. Examples of the amino alcohol include diethanolamine. The amount of the crosslinking agent can be 1 to 10 parts by mass when the polyol is 100 parts by mass. Only one type of crosslinking agent may be used, or two or more types may be used.

  Further, as the foam stabilizer, a linear or branched polyether-siloxane copolymer can be used. In particular, it is more preferable to use a linear polysiloxane-polyoxyalkylene copolymer having a low foam regulating power in order to improve the foaming ability of the foam. The compounding quantity of this foam stabilizer can be 0.5-15 mass parts (especially 1-4 mass parts), when a polyol is 100 mass parts. Only one type of foam stabilizer may be used, or two or more types may be used.

  Further, as the polyisocyanate, toluene diisocyanate, 1,5 naphthalene diisocyanate, methylene diphenyl diisocyanate (MDI), and modified products thereof can be used. As the polyisocyanate, crude MDI is preferable from the viewpoint of versatility and fluidity. Furthermore, carbodiimide-modified MDI is preferable from the viewpoint of heat resistance. Polyisocyanate can be normally made into the compounding quantity from which an isocyanate index will be 80-140 (especially 95-125). Only one type of polyisocyanate may be used, or two or more types may be used.

  A flame retardant can also be mix | blended with a foam raw material. In particular, when used for a heat insulating wall of a building, it is preferable to add a flame retardant. Examples of the flame retardant include aluminum hydroxide, metal / amine complex, ammonium polyphosphate, phosphine, tris (2,3-dichloropropyl) phosphonate, neopentyl brominated polyether, dibromopropanol, and dibromoneopentyl glycol. Is mentioned. As the flame retardant, a phosphate ester flame retardant having no halogen is more preferable.

  Hereinafter, the present invention will be specifically described with reference to the drawings.

(1) Configuration of Polyurethane Foam Manufacturing Apparatus A polyurethane foam manufacturing apparatus 1 according to the present embodiment, as shown in FIG. 1, contains a liquefied carbon dioxide supply apparatus 2 and a first liquid containing polyisocyanate as a main component. 1 container 3, a second container 4 containing a second liquid mainly composed of polyol, and a foaming machine 5 connected to these first container 3 and second container 4 (manufactured by Seven Tech Co., Ltd., model “ FS-2000N ") and a spray gun 6 (model" Fusion Gun "manufactured by Graco Gasmer) connected to the foaming machine 5.

  The liquefied carbon dioxide supply device 2 includes a liquefied carbon dioxide cylinder 8 (exemplified as a “carbon dioxide container” according to the present invention) that stores liquefied carbon dioxide, and nitrogen gas (exemplified as an “inert gas” according to the present invention). A nitrogen gas cylinder 9 (exemplified as an “inert gas container” according to the present invention) and a liquefied carbon dioxide pressurized container 10 (hereinafter also simply referred to as “pressurized container 10”). And a piston pump type metering pump 11 connected to the pressurized container 10 and a cooling unit 12 for cooling the metering pump 11 (illustrated as “temperature adjusting means” according to the present invention). .

  The supply port 8 a of the liquefied carbon dioxide cylinder 8 is provided with a regulator 14 for adjusting pressure. Further, a regulator 15 for pressure adjustment is provided at the supply port 9 a of the nitrogen gas cylinder 9. The pressurized container 10 includes a lower inlet 10a for injecting liquefied carbon dioxide from the liquefied carbon dioxide cylinder 8 from below, and an upper inlet 10b for injecting nitrogen gas from the nitrogen gas cylinder from above. And a lower supply port 10c for supplying liquefied carbon dioxide pressurized in the pressurized container 10 to the metering pump 11 from below.

  The lower inlet 10 a is connected to the regulator 14 of the liquefied carbon cylinder 8 through a pipe 17. The piping 17 is provided with a liquefied carbonic acid filling valve 77 and a check valve 99. The upper inlet 10 b is connected to the regulator 15 of the nitrogen gas cylinder 9 through the pipe 18. The pipe 18 is provided with a nitrogen gas filling valve 78 (pressurizing valve). Further, the lower supply port 10 c is connected to the metering pump 11 via the pipe 19. The pipe 19 is provided with a pressure relief valve 20, a liquefied carbon dioxide supply valve 79 to the metering pump 11, and a filter 100.

  In addition, it is preferable that the length of the piping 19 (for example, heat-resistant hose etc.) which connects the said pressurization container 10 and the metering pump 11 is 1220 mm or less and is as short as possible. If it is longer than 1220 mm, the pressure in the vicinity of the supply port to the metering pump 11 may decrease, and carbon dioxide may be vaporized. In this embodiment, the length of the pipe 19 is about 610 mm. Moreover, it is preferable that the internal diameter of the said piping 19 is 0.7-10.3 mm. If the pressure is less than 0.7 mm, the pressure loss is large, and the pressure in the vicinity of the supply port to the metering pump 11 may be reduced, so that carbon dioxide may be vaporized. In order to ensure pressure resistance, it is expensive and uneconomical. In this embodiment, the inner diameter of the pipe 19 is about 4.8 mm.

  The connecting pipe 21 that connects the branch pipe 18a branched from the pipe 18 and the pipe 19 includes a liquefied carbon dioxide (liquid phase) and a gas phase portion (nitrogen gas or carbon dioxide (gas phase) in the pressurized container 10 or A differential pressure gauge 22 (illustrated as “pressure difference measuring means” according to the present invention) for measuring the pressure difference with these mixtures) is provided. A blow valve 74 is provided at one end of the branch pipe 18a in order to reduce the pressure in the pressurized container 10 to less than the pressure of the liquefied carbon dioxide cylinder 8 when liquefied carbon dioxide is filled. The blow valve 74 can also be used for applications such as opening when the temperature rises above a predetermined temperature (for example, 40 ° C.) and lowering the temperature of the pressurized container 10 by the heat of vaporization of carbon dioxide. The connecting pipe 21 is provided with a pressure gauge 75.

  As shown in FIGS. 2 and 3, the metering pump 11 has a metal cylinder 23 including a plurality of block portions and flange portions. A first pressure chamber 24 and a second pressure chamber 25 are formed in the cylinder 23 so as to be spaced apart at predetermined intervals on both ends in the longitudinal direction.

  As shown in FIG. 4, a check valve 30 is provided on the inlet side of the first pressure chamber 24 of the cylinder 23. The check valve 30 is connected to one end of the pipe 19 (see FIG. 1). A check valve 31 is provided on the outlet side of the first pressure chamber 24 of the cylinder 23. This check valve 31 is connected to the second pressure chamber 25 via a connecting pipe 39. A check valve 41 is provided on the outlet side of the second pressure chamber 25 of the cylinder 23. The check valve 41 is connected to one end side of the pipe 43 (see FIG. 1).

  In the cylinder 23, a cylinder chamber 46 is formed between the first pressure chamber 24 and the second pressure chamber 25. A piston member 47 is supported in the cylinder chamber 46 so as to reciprocate along the axial direction. A first piston portion 49 that reciprocates within the first pressure chamber 24 is provided on one end side of the piston member 47. A second piston portion 50 that reciprocates within the second pressure chamber 25 is provided on the other end side of the piston member 47. The first piston portion 49 has a larger volume (substantially twice the volume) than the second piston portion 50.

  Further, the cylinder 23 is formed with a pair of port portions 51 a and 51 b that are connected to the cylinder chamber 46. Compressed air is supplied to each of the port portions 51 a and 51 b by a solenoid valve (not shown) at a predetermined pressure (for example, about 0.4 to 0.7 Mpa), and the piston member 47 is provided in the cylinder chamber 46. Is reciprocated. As a result, the first piston portion 49 is reciprocated in the first pressure chamber 24, and the second piston portion 50 is reciprocated in the second pressure chamber 25.

  In the metering pump 11 configured as described above, as shown in FIG. 4, from the state where the piston member 47 is positioned on one end side (left end side in FIG. 4), compressed air is supplied to the port portion 51a as shown in FIG. When the piston member 47 is moved toward the other end side (the right end side in FIG. 5), the first piston portion 49 moves in the first pressure chamber 24 to move from the pipe 19 into the first pressure chamber 24. The liquefied carbon dioxide is sucked, and the liquefied carbon dioxide in the second pressure chamber 25 is supplied to the foaming machine 5 side through the pipe 43 by the movement of the second piston portion 50 in the second pressure chamber 25. Then, as shown in FIG. 6, immediately before the movement of the piston member 47 proceeds to the other end side (the right end side in FIG. 6), a predetermined amount (first piston) is introduced into the first pressure chamber 24 from the pipe 19. The liquefied carbon dioxide having the same value as the volume of the portion 49; for example, 1.8 ml) is sucked. Further, a predetermined amount (approximately the same value as the volume of the second piston portion 49; for example, 0.9 ml) of the liquefied carbon dioxide in the second pressure chamber 25 is supplied to the foaming machine 5 side. As shown in FIG. 7, when the piston member 47 reaches the other end side (the right end side in FIG. 7), the suction of the liquefied carbon dioxide into the first pressure chamber 24 is stopped.

  Next, as shown in FIG. 8, when compressed air is supplied to the port portion 51 b and the piston member 47 is moved toward one end side (left end side in FIG. 8), the first pressure chamber 24 is moved to the first pressure chamber 24. Due to the movement of the piston portion 49, the liquefied carbon dioxide in the first pressure chamber 24 is sent into the second pressure chamber 25 via the connecting pipe 39, and the liquefied carbon dioxide in the second pressure chamber 25 is moved to the foaming machine 5 side. Supplied. Thereafter, as shown in FIG. 9, immediately before the movement of the piston member 47 proceeds to one end side (left end side in FIG. 9), a predetermined amount (first piston) of the liquefied carbon dioxide in the second pressure chamber 25 is reached. The value substantially equal to the difference between the volume of the portion 49 and the volume of the second piston portion 50; for example, 0.9 ml) is supplied to the foaming machine 5 side. And the above-mentioned operation is repeated and liquefied carbon dioxide is supplied quantitatively continuously from the metering pump 11.

  A stroke adjustment pin 53 is attached to one end side of the cylinder 23 by a nut 54 so that the position of the stroke adjustment pin 53 can be freely adjusted. The stroke of the reciprocating movement of the piston member 47 is adjusted by adjusting the protruding amount of the stroke adjustment pin 53. The amount can be adjusted.

  As shown in FIG. 2, the cooling unit 12 is attached to an outer surface portion forming the first pressure chamber 24 of the cylinder 23 with bolts (not shown). The cooling unit 12 includes a Peltier element 58 having a cooling plate 56 and a heat radiating plate 57. In this Peltier element 58, heat is transferred from the cooling plate 56 side to the heat radiating plate 57 side by passing a direct current. The cooling plate 56 is in contact with or opposed to the surface of the outer surface portion that forms the first pressure chamber 24 of the cylinder 23. The cooling unit 12 includes an electric fan 59. Further, a temperature sensor 60 for detecting the temperature of the liquefied carbon dioxide in the first pressure chamber 24 is embedded in the outer surface portion of the cylinder 23 forming the first pressure chamber 24. Furthermore, the cooling unit 12 includes a temperature controller 61 that controls the driving of the Peltier element 58 based on the detection result of the temperature sensor 60 and sets the temperature of the liquefied carbon dioxide to a predetermined value (for example, about 20 ° C.) or less. ing.

  Here, as shown in FIG. 10, the pipe 19 (43) is also referred to as a discoloration paint 63 (“temperature indicating paint”) that changes color due to a temperature change of the liquefied carbon dioxide flowing through the pipe 19 (43). ) Is applied. In the present embodiment, as the color changing paint 63, one that gradually changes color when the temperature of the pipe 19 (43) changes in the range of 10 to 20 ° C. is adopted. In addition, as the pipes 19 and 43, stainless steel overblades 19b and 43b are laminated on the outer circumference of the PTFE core tubes 19a and 43a (manufactured by Swagelok, model number “SS-4BT”).

  As shown in FIG. 1, each of the first container 3 and the second container 4 is an air-driven drum pump for supplying each liquid to the foaming machine 5 at a predetermined pressure (for example, about 1.5 Mpa). 65, 66 (manufactured by Graco Gasmer, model “OP232”).

  The foaming machine 5 has a proportion pump 67 for supplying the first liquid and the second liquid supplied to the foaming machine 5 to the spray gun 6. The pump 67 is a hydraulically driven piston pump, and the first liquid and the second liquid have a volume ratio of 1: 1 and a predetermined pressure (for example, about 8 to 9 MPa) by switching control of a solenoid valve (not shown). ) Is supplied to the spray gun 6 through the primary heater 68 and the heater hose 69. Furthermore, the foaming machine 5 includes a static mixer 70 (exemplified as a “mixing unit” according to the present invention) that is connected to one end of the pipe 43 and that mixes the second liquid and liquefied carbon dioxide.

  In the present embodiment, each of the primary heater 68 and the heater hose 69 is provided with a temperature sensor (not shown) for detecting the temperature of the liquid passing through the portions 68 and 69. Based on the ON / OFF control of the heaters 68 and 69, the first liquid and the second liquid are adjusted to temperatures necessary for transfer (viscosity adjustment) and foaming (mixing).

  The spray gun 6 has a chamber (not shown) connected to an air driven cylinder. When the trigger of the spray gun is pulled, the chamber slides, and the flow paths of the first liquid and the second liquid to the respective chambers. Is opened, and the first liquid and the second liquid are mixed, stirred and discharged in the chamber.

  Here, the cooling capacity required for the cooling unit 12 will be considered. Maximum liquefied carbon dioxide discharge amount of the pump: Amax [g / sec], specific heat of liquefied carbonic acid: c [J / g ° C.] (0.199 [cal / g ° C.], 1 cal = 4.186 J, 0.199 [ cal / g ° C.] × 4.186 [J / cal] = 0.833 [J / g ° C.]), maximum temperature of the atmosphere in which the pump is used (outside air temperature): TH [° C.], pump operating temperature (pump Temperature adjustment set temperature): TL [° C.], maximum heat absorption amount of the cooling means: Qmax [W], coefficient including energy loss (safety factor): Fs (1.6 times), Amax × c × A cooling unit having a maximum heat absorption amount Qmax set to (TH−TL) × Fs ≦ Qmax (Formula 1) is required. Theoretically, the maximum endothermic amount Qmax should be equal to or greater than Amax × c × (TH−TL) [w]. However, when actually operating, Fs is a coefficient that incorporates energy loss, and Amax × c × ( (TH-TL) × Fs [W] or more cooling capacity is required. In this example, Amax = 1.398 [g / sec], c = 0.833 [J / g ° C.], TH = 40 [° C.], TL = 20 [° C.], and Fs = 1.6. In this case, a cooling capacity of 1.398 × 0.833 × (40−20) × 1.6 = 37.265 or more may be selected from (Equation 1), and a Peltier element with Qmax = 39 W is provided. You are using a device. When CO2 is mixed with the foam having the above conditions (outside temperature of 40 ° C.) and an initial density of 80 kg / m 3, the following Table 1 is obtained.

  Below 35 W, carbon dioxide is vaporized in the pump, the pump causes cavitation, liquefied carbon dioxide cannot be pumped, and the foam density cannot be reduced. This cooling device uses DC12 [V] rectified by the power supply, and based on the detection result of the temperature sensor, the power is turned on when the temperature rises above the specified temperature (20 ° C), and the power is turned off below the specified temperature. is doing. Therefore, when 39W is used, the power supply is almost always on and the cooling device is in operation. Even if more Peltier elements are used, the OFF time only increases and there is no particular effect, but the apparatus becomes excessive. In addition, when the cooling device is attached to the second pressure chamber on the downstream side, the first pressure chamber can be cooled by conducting the pump surface, but the cooling capacity is insufficient, and CO2 cannot be pumped, resulting in a lower foam density. I didn't. When used for a long time, the temperature of the heat radiating plate rises. Therefore, a fan may be incorporated as in the embodiment to make it easier to radiate heat to the outside air.

(2) Operation of Polyurethane Foam Manufacturing Device Next, the operation of the polyurethane foam manufacturing device 1 having the above configuration will be described. In construction sites such as the formation of heat insulation walls at construction sites, etc., in addition to the set of manufacturing equipment 1 above, the compressor and generator etc. are loaded and transported to the loading platform of the work vehicle, and are constructed on site. Form a form.

  At the construction site, first, the pressurized container 10 is filled from the liquefied carbon dioxide cylinder 8 through the lower inlet 10a, and the pressure of the secondary liquefied carbon dioxide is a predetermined value (for example, about 5.6 Mpa). The handle of the regulator 14 is adjusted so that Then, liquefied carbon dioxide is filled until the display of the differential pressure gauge 22 reaches a predetermined value (for example, about 2.5 Kpa) (empirically, about 10 to 11 kgf of liquefied carbon dioxide is filled). Since the filling amount is proportional to the display value of the differential pressure gauge 22, filling is performed according to the supply amount on the day. Next, the pressure vessel 10 is filled with nitrogen gas from the nitrogen gas cylinder 9 through the upper inlet 10b, and the regulator 15 is set so that the pressure of the secondary side nitrogen gas becomes a predetermined value (for example, about 7.0 Mpa). Adjust the handle. Thereby, the inside of the pressurized container 10 is pressurized, and the pressure of the liquefied carbon dioxide is increased to a predetermined value (for example, about 7.0 Mpa). Further, when the amount of liquefied carbon dioxide decreases, the foaming ratio of the foam decreases. Therefore, the construction is temporarily stopped, the supply of nitrogen gas is stopped, the blow valve 74 is opened, and the pressure in the pressurized container 10 is reduced to 5%. After depressurization to less than 6 Mpa, liquefied carbon dioxide is supplied again into the pressurized container 10 by the above procedure.

In the present embodiment, the liquefied carbon cylinder 8 uses 30 kgf which is generally handled at a gas store or the like, and the nitrogen gas cylinder 9 includes 7 m ³ which is generally handled at a gas store or the like. Shall be used. In the present embodiment, the pressure setting on the secondary side of the regulator 14 of the liquefied carbon cylinder 8 is about 5.6 Mpa, but the setting pressure on the secondary side of the regulator 14 of the liquefied carbon cylinder 8 is 2.0. It is preferably ˜5.6 MPa. If it is less than 2.0 Mpa, it takes time to supply the liquefied carbon dioxide to the pressurized container 10, the pressure of the general-purpose liquefied carbon dioxide cylinder is 5.6 Mpa (20 ° C.), and it is not realistic. In this embodiment, the pressure setting on the secondary side of the regulator 15 of the inert gas (nitrogen gas) cylinder 9 is set to about 7.0 MPa. The pressure setting on the secondary side is preferably 6.0 to 10.0 MPa. If it is less than 6.0 MPa, the pressure in the vicinity of the supply port to the metering pump 11 may decrease, and carbon dioxide may be vaporized. If the pressure is higher than 10 MPa, the pressure of the carbon dioxide supply pump is set to be higher than that, and accordingly, the discharge pressure of the urethane foam raw material (isocyanate component, polyol component) must be increased to the same extent and set accordingly. In terms of properties, problems such as high pressure, difficulty in construction, and unstable quality occur.

  Next, the liquefied carbon dioxide filled in the pressurized container 10 is supplied to the metering pump 11 through the lower supply port 10c, and is pressurized to a predetermined value (for example, about 8.0 Mpa) by the metering pump 11. Then, a fixed amount is supplied to the foaming machine 5. In the metering pump 11, the temperature of the liquefied carbon dioxide is cooled by the cooling unit 12 so as to be a predetermined value (for example, about 20 ° C.) or less. Thereafter, the liquefied carbon dioxide supplied to the foaming machine 5 is mixed with the second liquid (polyol liquid) by the static mixer 70. Then, the first liquid and the second liquid are mixed and stirred by the operation of the spray gun 6 and discharged to obtain a polyurethane foam.

(3) Effect of Example As described above, in the polyurethane foam manufacturing apparatus 1 according to the present example, the liquefied carbon dioxide supply apparatus 2 includes the cooling unit 12 that cools the part that forms the first pressure chamber 24 in the cylinder 23. Therefore, it is possible to efficiently cool the liquefied carbon dioxide in the first pressure chamber 24 where the internal pressure is reduced when liquefied carbon dioxide is sucked in, thereby preventing vaporization, and to make the cooling unit 12 and the entire apparatus small and inexpensive. can do. As a result, liquefied carbon dioxide can be quantitatively and stably supplied to the foam raw material at the construction site and the like, and an excellent polyurethane foam having good construction and quality can be produced. In particular, in the present embodiment, since the metal cylinder 23 is employed, the entire cylinder 23 and the vicinity of the attachment of the pipe 19 on the suction side are suitably cooled by the cooling unit 12 by heat conduction. Furthermore, since the liquefied carbon dioxide supply device 2 is configured with a piston pump type metering pump 11, the piston pump is smaller and simpler in structure than other positive displacement pumps, pumps other than positive displacement pumps, and the like. Maintenance is also easy. When the pump for transferring liquefied carbon dioxide (metering pump) and the pump for transferring urethane foam raw material are the same type of piston pump, the control signal is used to synchronize the reciprocating motion of the piston by sharing the signals for driving both pumps. By doing so, it becomes easy to ensure the quantitativeness of the mixing of the liquefied carbon dioxide.

  Here, although the said liquefied carbon dioxide contributes as a foaming agent on polyurethane foam formation, when liquefied carbon dioxide is added, a cell diameter (bubble diameter) will become small. In general, it is known that the thermal conductivity decreases as the cell diameter decreases. When used as a heat insulating material for buildings, etc., if the thickness is the same, the heat insulating effect is increased, and the same heat insulating effect is also achieved. When it is going to obtain, a heat insulation layer can be made thin.

  In the present embodiment, the cooling unit 12 includes the Peltier element 58, so that the cooling unit 12 and the entire apparatus can be further reduced in size and cost.

  In the present embodiment, since the temperature sensor 60 is further provided, the temperature of the liquefied carbon dioxide is detected by the temperature sensor 60, so that the temperature control of the liquefied carbon dioxide can be performed. In particular, in this embodiment, since the temperature controller 61 performs drive control of the cooling unit 12 based on the detection result of the temperature sensor 60, the liquefied carbon dioxide can be cooled more efficiently.

  In this embodiment, since the color change paint 63 that changes color due to temperature change is applied to the surfaces of the pipes 19 and 43 connected to the metering pump 11, the temperature change of the liquefied carbon dioxide can be grasped visually by the color change of the color change paint 63. The temperature control of liquefied carbon dioxide can be performed.

  Further, in this embodiment, since the PTFE pipes 19 and 43 are employed, the temperature rise of the liquefied carbon dioxide can be more reliably suppressed because the thermal conductivity is lower than when steel pipes are employed.

  Further, in this embodiment, the measuring cylinder 11 is reciprocated in the first pressure chamber 24, and is connected to the first piston portion 49 and reciprocated in the second pressure chamber 25. And the second piston part 50 having a volume smaller than that of the first piston part 49. Therefore, the reciprocating movement of the first piston part 49 in the first pressure chamber 24 and the second piston part 50 in the second pressure chamber 25 are provided. By the reciprocating movement of the two-piston portion 50, the liquefied carbon dioxide can be quantitatively and more stably supplied.

  Moreover, in the polyurethane foam manufacturing apparatus 1 of the present embodiment, the liquefied carbon dioxide supply apparatus 2 is configured to include a specific pressurized container 10, and in this pressurized container 10, the liquefied carbon dioxide cylinder 8 is connected by the lower inlet 10 a. Since liquefied carbon dioxide is injected from below and nitrogen gas from the nitrogen gas cylinder 9 is injected from above through the upper inlet 10b, the liquefied carbon dioxide can be reliably pressurized in the pressurization vessel 10. . And then. Thus, since the liquefied carbon dioxide pressurized in the pressurization container 10 is supplied to the metering pump 11, vaporization of the liquefied carbon dioxide can be prevented. As a result, liquefied carbon dioxide can be quantitatively and stably supplied to the foam raw material at the construction site and the like, and an excellent polyurethane foam having good construction and quality can be produced. In particular, by providing the pressurized container 10, it is not necessary to employ a complicated and expensive vacuum heat insulating container as a container for storing liquefied carbon dioxide, and a generally used liquefied carbon dioxide cylinder 8 is used. Can do.

  Further, in the present embodiment, since the differential pressure gauge 22 is further provided, when the liquefied carbon dioxide is filled, the liquefied carbon dioxide in the pressurized container 10 and the gas phase part (inert gas or carbon dioxide) are filled by the differential pressure gauge 22. (Gas phase) or a mixture thereof) is measured. Therefore, the supply amount of liquefied carbon dioxide in the pressurized container 10 can be confirmed based on the measurement result of the pressure difference. And since the filling amount and the display value of the differential pressure gauge are approximately proportional, if the required amount is filled in the pressurized container 10 on the day of construction, a reduction in the expansion ratio due to the lack of liquefied carbon dioxide can be prevented.

  Furthermore, in this embodiment, since the lower supply port 10c for supplying the liquefied carbon dioxide pressurized in the container 10 to the metering pump 11 from below is provided in the pressurized container 10, the nitrogen gas is mixed. The liquefied carbon dioxide that is not in the state can be reliably supplied to the metering pump 11.

  In the present invention, the present invention is not limited to the above embodiment, and various modifications can be made within the scope of the present invention depending on the purpose and application. That is, in the said Example, although the form which supplies and mixes liquefied carbon dioxide to 2nd liquid (polyol liquid) was illustrated, it is not limited to this, For example, liquefied carbon dioxide is made into 1st liquid (polyisocyanate liquid). Supply / mixing may be performed, or liquefied carbon dioxide may be supplied / mixed to the first liquid (polyisocyanate liquid) and the second liquid (polyol liquid).

  Moreover, in the said Example, although the temperature sensor 60 which detects the temperature of the liquefied carbon dioxide in the 1st pressure chamber 24 indirectly was illustrated, it is not limited to this, For example, the liquefied dioxide in the 1st pressure chamber 24 is shown. It is good also as a temperature sensor which detects the temperature of carbon directly. In this case, it is preferable that a mounting hole that opens into the first pressure chamber 24 is formed in the cylinder 23 and a sheath type or protective tube type temperature sensor is attached to the mounting hole.

  Moreover, in the said Example, although the form which apply | coats the discoloration coating 63 to the surface of the piping 19 and 43 was illustrated, it is not limited to this, For example, it replaces with the piping 19 and 43 or adds to the surface of the cylinder 23. You may make it apply the color-change coating 63. FIG. Further, the color changing paint 6 may be applied to the surface of the pipe 17 or the connecting pipe 39.

  Furthermore, in the above embodiment, for example, as shown in FIG. 8, the heat dissipation plate 57 of the Peltier element 58 of the cooling unit 12 is connected to the raw material piping (pipe just before the heating unit by the primary heater 68) with good thermal conductivity. You may make it contact by the connection members 72, such as a metal. Thereby, energy loss can be reduced. Here, the communication member 72 constitutes a “heating means” according to the present invention.

  Widely used as a technology for producing polyurethane foam.

  DESCRIPTION OF SYMBOLS 1; Polyurethane foam manufacturing apparatus, 2; Liquefied carbon dioxide supply apparatus, 3; First container, 4; Second container, 8; Liquefied carbon cylinder, 9; Nitrogen gas cylinder, 10; Side inlet, 10b; Upper inlet, 11; Metering pump, 12; Cooling unit, 19, 43; Piping, 22; Differential pressure gauge, 23; Cylinder, 24; First pressure chamber, 25; Peltier element, 60; Temperature sensor, 63; Discoloration paint, 68; Primary heater, 72;

Claims (6)

A liquefied carbon dioxide supply device for supplying liquefied carbon dioxide, comprising a piston pump type metering pump having a metal cylinder in which a first pressure chamber on the upstream side and a second pressure chamber on the downstream side are formed,
A liquefied carbon dioxide supply apparatus comprising temperature adjusting means for adjusting a temperature of a portion forming the first pressure chamber in the metal cylinder.   The liquefied carbon dioxide supply device according to claim 1, wherein the temperature adjusting means includes a Peltier element.   The liquefied carbon dioxide supply device according to claim 1, further comprising a temperature sensor that detects a temperature of the liquefied carbon dioxide.   The liquefied carbon dioxide according to any one of claims 1 to 3, wherein a discoloration paint that changes color due to a temperature change is applied to a surface of at least one of the pipe connected to the metering pump and the metering pump. Feeding device. A liquefied carbon dioxide supply device according to any one of claims 1 to 4,
A first container containing a first liquid mainly composed of polyisocyanate;
A second container containing a second liquid mainly composed of polyol,
A polyurethane obtained by mixing liquefied carbon dioxide as a blowing agent supplied from the liquefied carbon dioxide supply device, a first liquid supplied from the first container, and a second liquid supplied from the second container. An apparatus for producing polyurethane foam, characterized by producing foam.   The temperature adjusting means of the liquefied carbon dioxide supply device has a Peltier element, and the first liquid supplied from the first container and the second container supplied from the second container using waste heat of the Peltier element. The polyurethane foam manufacturing apparatus according to claim 5, further comprising heating means for heating at least one of the two liquids.

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