JP4290794B2 - Continuous ice making steam exhaust type ice heat storage device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a water vapor exhaust type ice heat storage device in which a jet pump used as a water vapor exhaust means is a continuous ice making type.
[0002]
[Prior art]
Conventionally, alternative chlorofluorocarbons and chlorofluorocarbon refrigerants such as hydrofluorocarbons have been used for ice heat storage devices, but these refrigerants are not preferred because of their effects on the global environment such as ozone depletion and global warming. While the use of such chemical substances that harm the global environment is regulated, a non-Freon ice heat storage cooling system using water as a working medium using water as a working medium has been proposed by Japanese Patent Laid-Open No. 3-912623 filed by the present applicant. . Usually, a water vapor exhaust type ice heat storage device such as such an ice heat storage cooling system includes an ice heat storage tank and a water vapor exhaust means. In the ice heat storage cooling system, a jet pump is used as an example of the steam exhaust means.
[0003]
FIG. 7 shows a schematic configuration diagram of a conventional steam exhaust type ice heat storage device 1. The steam exhaust type ice heat storage device 1 includes an ice heat storage tank 2 and a jet pump. The jet pump has a steam generator 3, an ejector 4, and a condenser 5. The condenser 5 has a water path 14 for flowing cooling water. The ejector 4 is composed of an ejector body 6, a nozzle 7 and a diffuser 8.
[0004]
The diffuser 8 is further formed by sequentially reducing the inner diameter in the axial direction, a mixing portion 11 having an enlarged end at one end and a reduced end at the other end, and an inner diameter sequentially increasing in the axial direction. An enlarged portion 13 having a reduced end portion at one end and an enlarged end portion at the other end, and a throat portion 12 having both ends connected to the reduced end portion of the mixing portion and the reduced end portion of the enlarged portion. Yes.
[0005]
The operation of the jet pump is as follows. The driving steam generated from the steam generator 3 is expanded and accelerated in the nozzle 7, becomes a high-speed flow exceeding the Mach number 1 and flows into the ejector 4. The high-speed flow of the drive steam flowing into the ejector 4 sucks the generated steam (hereinafter simply referred to as secondary steam) in the ice heat storage tank 2, is mixed with the secondary steam in the diffuser 8, and diffuses into the condenser 5 while diffusing. To reach. In the condenser 5, the inflowing mixed steam is cooled and condensed by the cooling water flowing through the water path 14. The condensed water is returned to the ice heat storage tank 2 through the pump 9 and the steam generator 3 and the valve 10.
[0006]
On the other hand, in the ice heat storage tank 2, since the inside of the tank is depressurized by the jet pump and kept in a vacuum, a part of the water in the ice heat storage tank 2 evaporates below normal temperature, and the remaining water is cooled by the latent heat. The In this manner, the remaining water is stored in the ice heat storage tank 2 as cold water and / or ice.
[0007]
[Problems to be solved by the invention]
However, the conventional steam exhaust type ice heat storage device has the following problems. The secondary steam generated from the ice storage tank is close to the ice temperature. Further, the driving steam ejected from the nozzle expands rapidly in the diffuser. Therefore, when this secondary steam is sucked by the driving steam ejected from the nozzle and mixed in the mixing portion of the diffuser, the mixed steam generates condensed water having an ice temperature or lower. The condensed water below this ice temperature becomes ice and gradually adheres to the inner wall of the mixing section of the diffuser, obstructing the flow of the mixed steam. I could not.
[0008]
The present invention provides a steam exhaust type ice heat storage device that enables continuous ice making.
[0009]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the invention according to claim 1 exhausts water vapor generated by depressurizing the inside of the ice heat storage tank and the ice heat storage tank for storing water and / or ice to store heat. An exhaust means, and the exhaust means comprises an ejector, a steam generator that generates driving steam introduced into the ejector, and a condenser that condenses the driving steam injected from the ejector, The ejector includes an ejector body, a part of the ejector body provided in the ejector body, connected to the steam generator and ejecting drive steam, the drive steam ejected from the nozzle, and the ice heat storage. A diffuser that mixes the steam generated from the tank and guides the steam to the condenser while diffusing the mixed steam, and the diffuser is formed with an inner diameter sequentially reduced in the axial direction, A first cylindrical portion having an enlarged end portion and a reduced end portion at the other end, wherein the enlarged end portion is connected to the ejector body, and an inner diameter is sequentially enlarged in the axial direction. And a second cylindrical portion having an enlarged end portion at the other end, the enlarged end portion being connected to the condenser, a reduced end portion of the first cylindrical portion, and a reduced end portion of the second cylindrical portion A steam exhaust type ice heat storage device including both ends connected to each other, and the diffuser is disposed between the enlarged end portion of the first cylindrical portion and the enlarged end portion of the second cylindrical portion. A jacket is installed so as to surround it, and water is circulated inside the jacket, and the water circulated inside the jacket is expanded from the periphery of the enlarged end portion of the second cylindrical portion to the enlarged end portion of the first cylindrical portion. In the direction of the periphery of the The water, is characterized in that it has to flow to the periphery of the condenser.
[0011]
According to a second aspect of the invention, the steam exhaust type ice thermal storage apparatus of claim 1 Symbol placement, water introduced into the jacket is characterized in that a temperature range of 20 ° C. to 30 ° C..
[0012]
According to a third aspect of the invention, the steam exhaust type ice thermal storage apparatus of claim 2 Symbol placement, the diffuser is formed of a heat conductive material, inside times flowed the times running water of the jacket, the compression of the mixed vapor Thus, the enlarged portion of the diffuser that becomes high temperature is cooled by heat exchange, and the ice formed in the mixing portion of the diffuser is melted by heat exchange.
[0013]
The invention according to claim 4 comprises: an ice heat storage tank for storing water and / or ice etc. to store heat; and an exhaust means for exhausting water vapor generated by depressurizing the inside of the ice heat storage tank, The exhaust means includes an ejector, a steam generator that generates driving steam introduced into the ejector, and a condenser that condenses the driving steam injected from the ejector, and the ejector includes an ejector body, A part of the ejector body is provided and connected to the steam generator to inject driving steam, and the driving steam injected from the nozzle and steam generated from the ice heat storage tank are mixed. A diffuser for guiding the mixed vapor to the condenser while diffusing, and the diffuser is formed by sequentially reducing the inner diameter in the axial direction, and expanding at one end and reducing at the other end A first cylindrical portion in which the enlarged end portion is connected to the ejector body, an inner diameter is sequentially enlarged in the axial direction, a reduced end portion at one end, and an enlarged end portion at the other end And a third cylindrical portion having a second cylindrical portion connected to the condenser, a reduced end portion of the first cylindrical portion, and both ends connected to a reduced end portion of the second cylindrical portion. In a steam exhaust type ice heat storage device including a cylindrical part, a heat pipe is installed so as to surround the diffuser from a predetermined position of the first cylindrical part to a predetermined position of the second cylindrical part , A diffuser is formed of a heat conductor, and heat generated in the second cylindrical portion of the diffuser, which becomes high temperature due to compression of the mixed vapor, is transmitted to the first cylindrical portion of the diffuser by a heat pipe, and the inside of the first cylindrical portion Heat formed into ice It is characterized in that melted by conversion.
[0014]
According to a fifth aspect of the present invention, in the water vapor exhaust type ice heat storage device according to the fourth aspect , the predetermined position of the first cylindrical portion where the heat pipe is installed is a position cooled by the mixed steam. The predetermined position of the second cylindrical portion where the heat pipe is installed is a position where the temperature becomes high due to the compression of the mixed steam.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail based on the drawings, but the present invention is not limited to the following examples. In all the drawings, the same components are indicated by the same reference symbols and symbols.
[0017]
1, FIG. 2 and FIG. 3 are views showing an embodiment of a steam exhaust type ice heat storage device according to the present invention.
[0018]
As shown in FIG. 1, the water vapor exhaust type ice heat storage device 21 includes an ice heat storage tank 22 and a jet pump 23. The jet pump 23 includes a steam generator 24, an ejector 25, and a condenser 26. Further, the ejector 25 includes an ejector body 27, a nozzle 28, and a diffuser 29. The ice heat storage tank 22 is connected to the ejector body 27. The nozzle 28 is connected to the steam generator 24 and is installed in the ejector 25. The condenser 26 is connected to the diffuser 29, and further connected to the steam generator 24 via the pump 30 and to the ice heat storage tank 22 via the valve 31.
[0019]
Further, the diffuser 29 is provided with a stainless steel jacket 32 for circulating water so as to surround the periphery thereof.
[0020]
Here, “circular flow” means that the water introduced into the jacket flows evenly around the jacket.
[0021]
FIG. 2 shows a detailed cross-sectional view of the diffuser 29 provided with a jacket 32. The diffuser 29 includes a mixing portion 33 that mixes the drive steam injected from the nozzle 28 and the steam generated from the ice heat storage tank 22, a throat portion 34 that compresses and accelerates the mixed steam, and reduces the flow of the steam. And an enlarged portion 35 that guides the condenser 26 while diffusing.
[0022]
Here, the diffuser 29 is made of stainless steel. In addition to the above, circulating water in which the ice formed in the mixing portion of the diffuser, such as steel, copper, or plastic material, is circulated inside the jacket. It is preferable to use a heat transfer material having a thermal conductivity that can be melted by heat exchange of the mixture, and that the expanded portion of the diffuser that becomes high temperature by compression of the mixed steam can be cooled by heat exchange with the circulating water. .
[0023]
Between the inner wall of the jacket 32 and the outer wall of the diffuser 29, a plurality of partitions 32 d extend in a direction perpendicular to the axial direction of the diffuser 29 and are attached at regular intervals. These partitions are attached so as to contact the inner wall below the jacket 32 at the odd position Ln and to contact the inner wall above the jacket 32 at the even position Un. FIG. 3 shows a cross-sectional view of a plane including the L2 and U2 by separating the diffuser 29 provided with the jacket 32 shown in FIG. Here, these divisions 32 d are made of the same stainless steel as the jacket 32. 2 shows a diagram in which the mixing section 33, the throat section 34, and the expansion section 35 of the diffuser 29 are installed in a horizontal direction so that they are horizontally aligned. It may be installed in the vertical direction so as to be located above 35.
[0024]
Further, the jacket 32 has water outlets 32a and 32b in the vicinity of the enlarged end portion of the mixing portion 33 and in the vicinity of the enlarged end portion of the enlarged portion 35, respectively.
[0025]
In this embodiment, the partition 32d is attached to the jacket 32 so that flowing water circulates the partition 32d inside the jacket 32, the contact time between the flowing water and the inside of the diffuser 29 is lengthened, and the contact area is widened to transfer heat. Is done efficiently.
[0026]
For the jacket for circulating the flowing water, various methods can be used in which the flowing water flows through the entire periphery of the diffuser while keeping the contact time long, such as a spiral partition inside.
[0027]
Next, the operation of the steam exhaust type ice heat storage device 21 configured as described above will be described.
[0028]
In advance, tap water of about 25 ° C. is introduced into the water inlet 32b of the jacket 32 from the water supply via the tube t1. The water introduced into the jacket 32 circulates across the partition 32d in the order of L1, U1, L2, U2,... And flows out from the water outlet 32a. The water that has flowed out flows into the cooling water inlet 36a of the condenser 26 through the tube t2, flows through the water path 36 in the condenser, and flows out from the cooling water outlet 36b.
[0029]
Here, the water circulating in the jacket 32 is introduced using tap water. However, instead of the tap water, a pump or the like is used, and the water at an appropriate temperature is appropriately used in combination with a thermostatic bath or a cooling tower. Can flow at speed.
[0030]
Next, driving steam is generated from the steam generator 24. The generated driving steam is introduced into the nozzle 28, is expanded and accelerated in the nozzle 28, and flows into the diffuser 29 at a supersonic speed exceeding the Mach number 1, and the high-speed flow of the driving steam that flows in is the air and water vapor in the ice heat storage tank 22. Aspirate. Therefore, the inside of the ice heat storage tank 22 is maintained in a vacuum, and a part of the water in the ice heat storage tank 22 evaporates at a temperature close to the ice temperature and flows into the diffuser 29 as secondary steam. Then, the driving steam and the secondary steam flowing into the diffuser 29 are mixed in the mixing unit 33.
[0031]
Here, since the driving steam rapidly expands in the diffuser 29, when mixed with the secondary steam, the mixed steam generates condensed water below the ice temperature. However, since tap water of about 25 ° C. is flowing through the jacket 32 provided around the mixing portion 33 of the diffuser 29, the tap water transfers heat to the inside of the mixing portion 33, thereby condensing water below the ice temperature. As it warms, no ice is generated.
[0032]
Further, the mixed steam flows into the throat portion 34 of the diffuser 29 at supersonic speed, generates a pseudo shock wave at the throat portion 34 to cause a sudden compression rise, flows into the expansion portion 35 as subsonic velocity, and flows into the expansion portion 35. The pressure recovers and the temperature rises.
[0033]
At this time, the tap water circulating in the jacket 32 takes heat from the mixed steam in the enlarged portion 35 of the diffuser 29 and cools the mixed steam. Therefore, the circulating water in the jacket 32 is warmed, and when tap water of 25 ° C. is introduced, it becomes about 30 ° C. and flows around the mixing unit 33, so that heat can be transferred to the inside of the mixing unit 33 more efficiently. . At the same time, the circulating water flowing through the jacket 32 is cooled to condensate below the ice temperature inside the mixing unit 33, and reaches about 25 ° C.
[0034]
The mixed vapor further reaches the condenser 26 and is cooled and condensed by tap water circulating in the water path 36. The condensed water is returned to the ice heat storage tank 22 through the pump 30 and the steam generator 24 and the valve 31.
[0035]
In the series of processes described above, in the ice heat storage tank 22, a part of the evaporated water cools the water itself by its latent heat, and the remaining water is made.
[0036]
Thus, according to the steam exhaust type ice heat storage device 21 according to the present invention, the mixed steam of the driving steam injected from the nozzle and the secondary steam generated from the ice heat storage tank generates ice in the mixing portion of the diffuser. Thus, the problem of the conventional steam exhaust type ice heat storage device that hinders the flow of the mixed steam can be solved, and the ice storage tank can be efficiently sucked into the ice making continuously.
[0037]
4 and 5 are views showing another embodiment of the steam exhaust type ice heat storage device according to the present invention.
[0038]
As shown in FIG. 4, the steam exhaust type ice heat storage device 41 has substantially the same structure as the steam exhaust type ice heat storage device 21 shown in FIG. 1, and the same components are denoted by the same reference numerals as in FIG. Show. The steam exhaust type ice heat storage device 41 includes an ice heat storage tank 22 and a jet pump 43. The jet pump 43 includes a steam generator 24, an ejector 45, and a condenser 46. Further, the ejector 45 includes an ejector main body 47, a nozzle 48, and a diffuser 49. The condenser 46 has a water path 56 for flowing cooling water. Further, a heat pipe 52 is provided around the diffuser 49.
[0039]
FIG. 5 shows a detailed cross-sectional view of the diffuser 49 provided with the heat pipe 52. The heat pipe 52 has the same structure as a known heat pipe. That is, the heat pipe 52 is installed so as to surround the outer wall of the diffuser 49, and the space between the inner wall of the heat pipe 52 and the outer wall of the diffuser 49 is sealed. A small amount of evaporating liquid such as water is introduced as a working liquid into the sealed portion. Further, the heat pipe 52 may be provided with a wick or a groove. When the wick or the groove is provided, it is preferably provided in the heat pipe 52 along the outer diameter of the diffuser 49 as indicated by 57 shown in FIG.
[0040]
The heat pipe is made of stainless steel, steel, copper, aluminum, or the like. Further, as the working liquid of the heat pipe 52, alcohol such as methanol, ammonia, or the like may be used in addition to water.
[0041]
Below, the preferable installation position of the heat pipe 52 to the diffuser 49 and the effect | action of the water vapor exhaust type ice heat storage apparatus 41 comprised in this way are demonstrated.
[0042]
First, the steam temperature in the diffuser 4 during driving was measured using the conventional steam exhaust type ice heat storage device 1 shown in FIG. An enlarged sectional view of the diffuser 4 is shown in FIG. The diffuser 4 used here is made of stainless steel, has an enlarged end portion diameter of 44 mm, a throat diameter of 18 mm, an enlarged end portion diameter of 46 mm, a total length of 498 mm, a mixing portion of 198 mm, and a throat portion of 100 mm. The enlarged portion was 200 mm.
[0043]
The temperature of the steam in the diffuser 4 is a position 450 mm from the position of 50 mm from the enlarged end face 11 e in the direction from the enlarged end of the mixing part 11 of the diffuser 4 shown in FIG. 6 to the enlarged end of the enlarged part 13. Measurement was performed at a position (hereinafter referred to as the position of the diffuser) moved by 50 mm. The measurement result about the case where the temperature in the ice thermal storage tank 2 is 0.1 degreeC and 1.5 degreeC is shown in FIG. As shown in FIG. 7, it was 20 ° C. or less at the diffuser position 100 mm, about 0 ° C. at the position 150 mm, and 10 ° C. or less at the position 200 mm. On the other hand, it was found that the steam temperature was about 50 ° C. or more at the diffuser position of 400 mm.
[0044]
By the way, when one end of the heat pipe is heated, the working liquid sealed inside evaporates. At this time, when the other end is cooled, the vapor condenses at the other end and returns to the liquid. In addition, the condensate returns to one end being heated through the wick in the heat pipe by capillary action or by gravity. With such a mechanism, the heat pipe can efficiently transfer heat from the heated evaporation section at one end to the condensing section at the other end being cooled.
[0045]
From the above, for example, when a diffuser 49 having the same material and the same size as the diffuser 1 is used, it can be seen that a point at a diffuser position of 400 mm can serve as an evaporating part, and a point near the diffuser position at 150 mm can serve as a condensing part.
[0046]
Here, the diffuser 49 is made of stainless steel, but in addition, the heat inside the diffuser 49 such as steel, copper, plastic material, etc. can be transferred to the working liquid in the heat pipe 52 and operated. It is preferable to use a heat transfer material having a thermal conductivity that can transfer the heat of the liquid into the diffuser.
[0047]
Therefore, in this example, as shown in FIG. 5, the heat pipe 52 is placed around the diffuser 49 so that one end of the heat pipe 52 is positioned at about 400 mm with the evaporation portion 58 and the other end is at about 150 mm with the condensation portion 59. It is good to install. If it does in this way, the working liquid of heat pipe 52 will be heated and evaporated in evaporation part 58, will be efficiently transmitted to condensation part 59, and working liquid will be condensed here. The working liquid condensed into liquid by the condensing unit 59 returns to the evaporation unit 58 through the wick 57 in the heat pipe 52. In the condensing part 59 at a position of about 150 mm, heat is transferred from the heat pipe 52 to the inside of the mixing part 53 of the diffuser 49, and the condensed water below the ice temperature is warmed, so that no ice is generated.
[0048]
When the ejector 45 is installed in the vertical direction and the mixing portion 53 of the diffuser 49 is positioned above the expansion portion 55 of the diffuser, the condensing portion 59 of the heat pipe 52 is positioned above the evaporation portion 58. Therefore, the working liquid can be returned to the evaporation unit 58 using gravity without providing the wick 57 in the heat pipe 52. If it does in this way, the structure of a heat pipe can be simplified more.
【The invention's effect】
According to the invention of claim 1, mixing of the diffuser is performed by installing a jacket so as to surround the diffuser from the enlarged end portion of the mixing portion to the enlarged end portion of the enlarged portion and circulating water through the jacket. The ice generated by the mixed steam formed in the section can be melted by heat exchange with the circulating water to prevent the generation of ice, and the flow of the mixed steam is not hindered. Can be made efficiently and continuously.
[0049]
According to invention of Claim 2 thru | or 4, the mixed steam in the expansion part which becomes high temperature by compression of mixed steam with water introduced into the jacket is cooled, and the mixed steam formed in the mixing part of the diffuser with the water Ice can be melted by heat exchange, and the circulating water cooled by heat exchange can be used as cooling water for the condenser, and the running water can be used more efficiently.
[0050]
It is also possible to use the running water that flows out from the periphery of the mixing section as the cooling water for the condenser that becomes hot due to the compression of the mixed steam, and the cooling water required for the conventional condenser can be used together with the circulating water in the jacket. Furthermore, continuous ice making can be performed more efficiently and simply.
[0051]
According to invention of Claim 5 thru | or 7, the mixing formed in the mixing part of a diffuser by installing a heat pipe so that a diffuser may be surrounded from the predetermined position of a mixing part to the predetermined position of an expansion part. Ice can be melted by heat exchange with the working fluid of the heat pipe to prevent the generation of ice, and the flow of mixed steam is not hindered, so the distribution area of mixed steam in the diffuser can be secured, Ice can be made efficiently and continuously.
[0052]
[Brief description of the drawings]
FIG. 1 is a schematic view showing an embodiment of a water vapor exhaust type ice heat storage device according to the present invention.
FIG. 2 is a schematic view showing a diffuser that constitutes a part of the steam exhaust type ice heat storage device shown in FIG. 1;
FIG. 3 is a cross-sectional view of the diffuser shown in FIG.
FIG. 4 is a schematic view showing another embodiment of the water vapor exhaust type ice heat storage device according to the present invention.
5 is a schematic view showing a diffuser that constitutes a part of the water vapor exhaust type ice heat storage device shown in FIG. 4. FIG.
FIG. 6 is a schematic view showing a diffuser constituting a part of a conventional steam exhaust type ice heat storage device.
FIG. 7 is a graph showing the relationship between the position in the length direction of the diffuser and its internal temperature.
FIG. 8 is a schematic view showing a conventional steam exhaust type ice heat storage device.
[Explanation of symbols]
21, 41 Water vapor exhaust type ice heat storage device 22 Ice heat storage tank 23, 43 Jet pump (exhaust means)
24 Steam generator 25, 45 Ejector 26, 46 Condenser 27, 47 Ejector body 28, 48 Nozzle 29, 49 Diffuser 32 Jacket 33, 53 Mixing section (first cylindrical section)
34, 54 throat (third cylindrical part)
35, 55 Enlarged part (second cylindrical part)
52 Heat pipe 57 Wick or groove 58 Evaporating part 59 Condensing part

Claims (5)

An ice storage tank for storing water and / or ice to store heat;
Exhaust means for exhausting water vapor generated by depressurizing the inside of the ice heat storage tank,
The exhaust means includes an ejector, a steam generator that generates driving steam introduced into the ejector, and a condenser that condenses the driving steam injected from the ejector,
The ejector includes an ejector body, a part of the ejector body provided in the ejector body, connected to the steam generator and ejecting drive steam, the drive steam ejected from the nozzle, and the ice heat storage. A diffuser that mixes the steam generated from the tank and guides it to a condenser while diffusing the mixed steam;
The diffuser is
A first cylindrical portion formed by sequentially reducing an inner diameter in the axial direction, having an enlarged end portion at one end thereof and a reduced end portion at the other end, and the enlarged end portion being connected to the ejector body;
An inner diameter is sequentially enlarged in the axial direction, and has a reduced end portion at one end and an enlarged end portion at the other end, and the enlarged cylindrical end portion is connected to the condenser;
In the steam exhaust type ice heat storage device, including a reduced end portion of the first cylindrical portion and a third cylindrical portion having both ends connected to the reduced end portion of the second cylindrical portion,
Installing the jacket so as to surround the diffuser between the enlarged end portion of the first cylindrical portion and the enlarged end portion of the second cylindrical portion, and causing water to circulate inside the jacket ;
Water that is circulated inside the jacket flows from the periphery of the enlarged end portion of the second cylindrical portion toward the periphery of the enlarged end portion of the first cylindrical portion, and from the periphery of the enlarged end portion of the first cylindrical portion. A water vapor exhaust type ice heat storage device characterized in that the discharged water is also allowed to flow around the condenser. The water vapor exhaust type ice heat storage device according to claim 1, wherein water introduced into the jacket is in a temperature range of 20 ° C to 30 ° C. 3. The steam exhaust type ice heat storage device according to claim 2, wherein the diffuser is formed of a heat conductor, and the circulating water that is circulated inside the jacket has a high temperature due to compression of the mixed steam. A steam exhaust type ice heat storage device characterized in that the cylindrical portion is cooled by heat exchange and the ice formed in the first cylindrical portion of the diffuser is melted by heat exchange. An ice storage tank for storing water and / or ice to store heat;
Exhaust means for exhausting water vapor generated by depressurizing the inside of the ice heat storage tank,
The exhaust means includes an ejector, a steam generator that generates driving steam introduced into the ejector, and a condenser that condenses the driving steam injected from the ejector,
The ejector includes an ejector body, a part of the ejector body provided in the ejector body, connected to the steam generator and ejecting drive steam, the drive steam ejected from the nozzle, and the ice heat storage. A diffuser that mixes the steam generated from the tank and guides it to a condenser while diffusing the mixed steam;
The diffuser is
A first cylindrical portion formed by sequentially reducing an inner diameter in the axial direction, having an enlarged end portion at one end thereof and a reduced end portion at the other end, and the enlarged end portion being connected to the ejector body;
An inner diameter is sequentially enlarged in the axial direction, and has a reduced end portion at one end and an enlarged end portion at the other end, and the enlarged cylindrical end portion is connected to the condenser;
In the steam exhaust type ice heat storage device, including a reduced end portion of the first cylindrical portion and a third cylindrical portion having both ends connected to the reduced end portion of the second cylindrical portion,
A heat pipe is installed so as to surround the diffuser between a predetermined position of the first cylindrical portion and a predetermined position of the second cylindrical portion,
The diffuser is formed of a heat conductor, and heat generated in the second cylindrical portion of the diffuser, which becomes high temperature due to compression of the mixed vapor, is transmitted to the first cylindrical portion of the diffuser by a heat pipe, and the first cylinder A water vapor exhaust type ice heat storage device characterized in that ice formed in the section is melted by heat exchange. The steam exhaust type ice heat storage device according to claim 4, wherein the predetermined position of the first cylindrical portion where the heat pipe is installed is a position cooled by the mixed steam, and the heat pipe is installed. The water vapor exhaust type ice heat storage device, wherein the predetermined position of the second cylindrical portion is a position that becomes high temperature by compression of the mixed steam.

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