KR101350947B1 - Ice making device - Google Patents

Abstract

Ice making apparatus according to an embodiment of the present invention is a heat exchanger that absorbs heat energy while the refrigerant evaporates, a plurality of heat exchange passages are installed in the transverse inside of the heat exchanger to exchange heat with the refrigerant while the heat medium passes, the heat exchange passage An inlet chamber in communication with the heat exchange passage, the heat medium flowing in the heat exchange passage, a discharge chamber in which the heat medium exchanged with the heat exchange passage is discharged from the heat exchange passage, a rod-shaped rod member, and a spiral outside the rod member. It includes a blade protruding in the shape and is inserted into the heat exchange passage, and includes a scraper for moving the heat medium from the inlet chamber to the discharge chamber direction and a driving unit for providing a driving force of the scraper. According to such a configuration, a scraper having a spiral blade is used, and the scraper is formed to extend to the inlet chamber or the outlet chamber so that the heat medium is smoothly stirred in the inlet chamber or the outlet chamber. Clogging or aggregation can be prevented.

Description

Ice maker {ICE MAKING DEVICE}

Disclosed is an ice making apparatus capable of performing ice making using heat energy absorption due to evaporation of a refrigerant. More specifically, an ice making apparatus is disclosed, which improves efficiency and productivity by changing a structure for heat exchange between a refrigerant and a heat medium.

In general, ice slurry has excellent characteristics compared to the existing methods in heat storage, fluidity, cooling characteristics, and sea ice characteristics, and thus is expected to play a large role in heat storage and cold heat transportation, and is recognized as one of the core technologies of the next generation heating and cooling system. It has been going on, but its supply has been stagnant for many years. Many scholars and researchers believe that the cause of this sluggishness is the absence of an ice machine that is economical, reliable, capable of large capacity, and easy to follow up. Therefore, the first solution for expanding the role of the ice slurry is to secure a reliable economic ice making device due to problems related to ice making.

This ice making device is partly demonstrated in the products using the vertical shell and tube heat exchanger, which is currently available in the shell & tube heat exchanger type ice making machine among the various heat exchanger types developed to date. However, the vertical shell & tube type products developed so far cannot exceed 500kW / unit at the maximum capacity. In addition, in the case of the US product is difficult to operate when the ice particles are introduced into the ice making device is difficult to apply directly to the transport system, the domestic product has a disadvantage that increases as the power of the circulating pump power during ice ice ice making large capacity.

In the whip rod method of US Pat. No. 5,768,894, the heat accumulating medium flows over the edge of the heat pipe using gravity from the top, so that a uniform amount of heat storage medium flows into the heat pipes, and then the whip rod is moved inside the heat pipe. As it rotates at high speed by orbital operation and closes the inner surface of the heat exchanger tube by centrifugal force, the ice layer is not fixed and ice slurry is formed and flows down by gravity to the lower part of the heat exchanger tube. Ice slurries are produced and discharged with a structure that inhales and discharges a little more or the same amount. However, in this device, the heat medium flow rate of the inlet chamber becomes very slow for even distribution, so even if a small amount of ice particles enters the ice maker inlet chamber Ice particles on top Eventually clog. Even with extremely fluid additives, this problem is not easily solved. When the product is connected to a heat storage tank for direct transportation, a large amount of ice particles are forced into the heat medium inlet connected to the heat storage tank, which frequently causes clogging in the inflow chamber of the ice making device, making operation very difficult. For this reason, this product is not used for direct transportation but is mainly used for cooling ice storage systems using ice bed type heat storage tanks. Moreover, due to the strength of the drive plate, which is a core part of the power transmission parts, it is difficult to manufacture a large-capacity product, which is not suitable for a large-scale heat source system such as district cooling that requires a large capacity. There is a lot of cost, and there is a considerable problem in the control problem for the discharge of ice slurries. In Korea Patent 10-0513219, one of the essential technical elements of the ice making device must be able to discharge the ice sludge from the ice making machine to the outside effectively. As a concrete form, it suggests the installation of the inclined guide board in the direction of exit in the counter flow type and the exit chamber. However, in order to discharge the ice from the ice maker, additional pump lift requires 0.2 ~ 0.8 bar additional lift than circulating aqueous solution only depending on the size of the ice maker. The power loss is even greater when considering the basic lift for distribution. In addition, when ice slurries containing a large amount of ice particles are introduced into the ice making apparatus, partial separation may occur due to phase separation at the inlet during distribution. Therefore, the ice making device to be used in the ice sludge direct transportation system that inevitably enters the ice slurry into the ice making device needs a more perfect discharge and clogging prevention device.

Meanwhile, de-icing devices developed in Europe and North America include single tube scraper type products, disk type, vacuum type, and fluidized bed type, but all are not suitable for use as heat source equipment due to lack of price competitiveness or low capacity, There is a problem and it is only used for a specific purpose. Small-capacity single tube products are used in some areas such as cooling of aquatic products due to limitations in capacity and lack of price competitiveness despite excellent reliability and excellent circulation characteristics. Only a few facilities are in operation, and it is particularly difficult to commercialize the ice produced from vacuum to atmospheric pressure.

In the case of the fluidized bed type, it is difficult to separate the ice particles and the metal or plastic balls used in the fluid state, and the height of the installation is very high. The slippery method that can make ice while smoothing the surface of evaporator plate developed at the laboratory level to prevent the adhesion of ice particles is possible, but surface contamination caused by long-term operation and the device to prevent it and the durability of the surface material There are questions about the situation, and the operating conditions are very demanding, so it is not yet known whether they will be able to be practically competitive.

Recently, the multi-layer disk & brush deicing method developed in Canada is known to be capable of 500kW / unit, but there seems to be no proper way to recover the ice sludge produced.

The overcooling of the supercooled water using the supercooling of water mainly developed in Japan has also made a number of technological advancements and has been applied to ice storage systems. However, the supercooled water type is an ice slurry obtained by direct cooling of water, which is a characteristic and advantage, but does not use additives, but there are many problems in direct transportation, especially clogging (blocking by phase separation) and agglomeration, recrystallization. And bridging due to bridging phenomenon) are difficult to transport directly, and the ice making apparatus has a disadvantage in that it is difficult to use in a direct transportation system because blockage occurs when ice particles are introduced. In addition, in order to continuously make the supercooled water, it is necessary to remove the fine dust contained in the water used for ice making, so it is a high-performance filter and a preheating device to block the inflow of ice particles, an indirect cooling evaporator that cannot be directly exchanged with the refrigerant, and a continuous In spite of the disadvantages that the spare equipment for driving is necessary, it is becoming more complicated than the scraper type and is being contracted despite the technical superiority.

Recently, the scraper type is being developed again. However, in order to eliminate the wear phenomenon of the whip rod and the heat pipe by improving the American product, the method of coating the outer surface of the whip rod with plastic material has a problem of driving method and the size of the whip rod. It seems that ice particles are not flowing smoothly as they grow, causing ice slurry circulation problems and congestion problems in the inlet chamber for distribution.

In conclusion, there is no ice making device that can be used as a part of heat source equipment, and the problems that must be solved in order for the ice slurry system to be widely used as a heat source equipment are to secure economic feasibility, increase the capacity, and solve the clogging problem in circulation.

According to one embodiment of the present invention, it is to provide an ice making apparatus that can change the structure for heat exchange between the refrigerant and the heat medium to improve the efficiency and productivity and increase the capacity.

According to one embodiment of the present invention, to minimize the clogging and agglomeration of the ice slurry in the device to prevent overload of the components, to provide an ice making apparatus that can expect the flow of the ice slurry efficiently.

An ice making apparatus according to an embodiment of the present invention includes a heat exchanger that absorbs thermal energy while the refrigerant evaporates, a plurality of heat exchange passages installed horizontally inside the heat exchanger, and heat exchange with the refrigerant while the heat medium passes through the heat exchange passage. An inflow chamber in communication with the heat medium, the heat medium flowing into the heat exchange passage, a discharge chamber in which the heat medium exchanged with the heat exchange passage is discharged from the heat exchange passage, a rod-like rod member, and a spiral shape outside the rod member. And a blade formed to protrude into the heat exchange passage, the scraper being inserted into the heat exchange passage and rotating to move the heat medium from the inlet chamber to the discharge chamber to prevent the phase change of the heat medium from sticking to the heat transfer surface and to increase the heat transfer effect. It includes a drive unit for providing a driving force of the scraper.

According to one side, the at least one scraper may be formed to extend into at least one of the inlet chamber or the discharge chamber.

According to one side, the ice making apparatus further comprises a stirring unit, the stirring unit includes a plurality of paddles formed in a radial, the image of the heat medium when disposed in at least one of the discharge chamber or the inlet chamber to rotate It is arranged to suppress clogging due to separation.

According to one side, the gap between the end of the blade and the inner surface of the heat exchange passage is preferably formed in 0.1mm or more and 0.4mm or less.

According to one side, the cross-sectional shape of the blade is one side is provided with a curved surface, the other side is preferably provided in at least one shape of a combination of one straight line or a plurality of straight lines.

According to one side, the ice making apparatus preferably further comprises at least one support member for supporting the heat exchange passage, the support member is more preferably provided with a plastic material.

According to one side, the discharge chamber further comprises a discharge port formed to discharge the heat medium to the outside and a guide plate formed in a flat plate shape inclined with respect to the heat exchange passage to guide the heat medium in the discharge port direction.

According to one side, the guide plate is disposed so that a portion of the scraper penetrates.

According to one side, the inlet chamber is in communication with the outside is formed with a plurality of inlets for introducing the heat medium inside, the plurality of inlets may be arranged in a direction symmetrical with each other about the inlet chamber or radially disposed. .

First, using a scraper provided with a spiral blade, the scraper is formed to extend to the inlet or outlet chamber so that the heat medium is stirred in the inlet or outlet chamber smoothly, clogging by phase separation of the solid-liquid mixed heat medium Agglomeration can be prevented.

Second, congestion that may occur as the flow rate of the heat medium flowing into the inlet from the inlet and the distance from each heat exchange passage in the inlet may be prevented by the scraper extending into the inlet.

Third, in spite of the relatively low rotational speed of the scraper, the gap between the scraper and the inner surface of the heat exchange passage is maintained to effectively suppress the phase change of the heat medium from being fixed to the inner surface of the heat exchange passage, thereby enabling stable operation.

Fourth, by maintaining the above-described shape of the blade of the scraper and a constant gap between the blade and the heat exchange passage, the positional deviation between the stopper and the driving of the scraper is reduced, and the scraper converges from the inside of the heat exchange passage to the center during driving, so that the heat exchange passage is gravity There is an advantage that can be placed regardless of the direction.

Fifth, by keeping the ice making machine horizontal, the boiling condition of the refrigerant outside the heat exchange passage can be maintained in the optimal nuclear boiling state, thereby improving the heat transfer efficiency, and in case of arranging the drive unit horizontally and vertically. Relatively favorable maintenance, it can be provided with a relatively long length of the heat exchange passage has the advantage that a large amount of heat exchange is possible according to the strength of the drive unit.

Sixth, there is an advantage that the stirring unit can guide the heating medium in the circulation or outlet direction to suppress clogging or aggregation.

Seventh, the scraper, which was settled downward due to the influence of gravity at the time of stopping, converges to the center of the heat exchange passage, so the longitudinal movement distance of the scraper is very small, minimizing the generation of vibration due to the driving, and abnormal blockage of the heat exchange passage. Even when a force is applied to the scraper, since the heat exchange passage outside the scraper is fixed by the support member, vibration is suppressed and vibration is absorbed due to the elasticity of the plastic material, thereby reducing the expansion of vibration to other parts.

1 is a cross-sectional view showing a cross section of the ice making apparatus according to an embodiment of the present invention;
2 is a cross-sectional view taken along the line II of FIG.
3 is a partial cross-sectional view showing a modified part of the ice making apparatus shown in FIG.
4 is a cross-sectional view taken along the line II-II of FIG. 3;
5 is a sectional view showing a cross section of another ice making apparatus according to another embodiment of the present invention;
6 is a cross-sectional view taken along the line III-III of FIG.
7 is a measurement graph showing a change in scraper power during an ice making operation of a conventional ice making apparatus;
And,
8 is a graph showing the change of the scraper power during the ice making operation of the ice making apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments.

An ice making apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2 as follows. 1 is a cross-sectional view showing a cross-section of the ice making apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view taken along the line I-I of FIG.

As shown therein, the ice making apparatus includes a heat exchanger 100, a heat exchange passage 110, an inflow chamber 120, a discharge chamber 130, a scraper 200, and a driving unit 170.

The heat exchanger 100 is a commonly used heat exchanger that allows the refrigerant to absorb heat energy while evaporating. The heat exchanger 100 has a space therein, and absorbs heat energy from a heat medium to be described later when evaporating by introducing an external refrigerant into the space. do.

The heat exchange passage 110 is horizontally installed inside the heat exchanger 100 so as to exchange heat with the refrigerant while the heat medium passes therethrough, and is formed in a hollow pipe shape, and a plurality of heat exchange passages 110 are provided. The heat exchange passage 110 is preferably provided with a surface-treated copper tube whose surface is processed to promote nuclear boiling, but is not limited thereto.

The inlet chamber 120 communicates with the heat exchange passage 110, and is provided at one side of the heat exchanger 100 so that the heat medium flows into the heat exchange passage 110, and the discharge chamber 130 also performs heat exchange. In communication with the passage (110), the heat medium is provided to be discharged from the heat exchange passage (110), and is arranged on the opposite side where the inlet chamber (120) is formed around the heat exchanger (100).

At this time, the inlet chamber 120 has an inlet 125 communicating with the outside is formed so that the heat medium is introduced into the inlet chamber 120, the heat medium in which the heat exchange is completed to the outside in the discharge chamber 130 That is, the outlet 135 for discharging the ice slurry to the outside is formed, a description thereof will be described later with reference to FIG.

The scraper 200 includes a rod member 210 and a blade 220. The rod member 210 is formed in a rod shape and is formed to be relatively longer than the length of the heat exchange passage 110 so that the rod member 210 is formed to extend outwardly by a predetermined length to the outside of the inflow chamber 120 and the discharge chamber 130. Preferably, but not limited to, but not limited to, for example, formed to the same length as the length of the heat exchange passage 110 or extends into one of the inlet chamber 120 or the discharge chamber 130. Of course it is possible.

The blade 220 is formed to protrude in a spiral shape on the outside of the rod member 210, the cross-sectional shape of the blade 220 is curved on one side of the front portion according to the direction in which the scraper 200 rotates It is provided with, the other side is provided in the shape or curve formed in one or more straight lines.

At this time, the scraper 200 is inserted into the heat exchange passage 110 is disposed, and as the scraper 200 rotates from the inlet chamber 120 by the action of the spiral of the blade 220 The heat medium introduced into the heat exchange passage 110 moves toward the discharge chamber 130 along the heat exchange passage 110 to be brought into contact with the outer surface of the heat exchange passage 110 to perform heat exchange. In other words, the scraper 200 moves the heat medium toward the discharge chamber 130 and suppresses the heat-changed heat medium from sticking to the inner surface of the heat exchange passage 110, that is, the heat transfer surface, and reduces the heat transfer effect. It is provided to increase.

The driving unit 170 is connected to a gear device connected to the motor and a motor commonly used to provide a rotational driving force of the scraper 200, but is not limited thereto or limited to, and outputs an output capable of operating the ice making device. Of course, if the electric motor that can provide a driving force for rotating the scraper 200 can be freely changed.

Therefore, the scraper 200 is provided with the spiral blade 220, and the scraper 200 extends to the inflow chamber 120 and the discharge chamber 130, and thus the scraper 200. ) Can prevent clogging or agglomeration by phase separation of the heat medium, in particular the solid-liquid mixed heat medium, so that the heat medium can flow smoothly in the inlet chamber 120 or the discharge chamber 130.

In addition, the scraper 200 corresponding to a portion in which the main flow forming the center of the heat medium flow occurs in the scraper 200 is provided so as not to extend to the discharge chamber 130 or the inlet chamber 120. It will be understood by anyone that it can lead to a smooth flow.

In addition, in the ice making apparatus of the above-described structure, as the heat medium enters the inlet chamber 120 of the ice making apparatus, the flow velocity is slowed by the cross-sectional area that is widened, and the flow velocity of each portion is not constant, Congestion that may occur as the distance from the heat exchange passage 110 is different may be prevented by the scraper 200 extending to the inflow chamber 120.

In addition, the pressure drop in the heat exchange passage 110 is 0.3 ~ 0.8 bar, the flow according to the difference in the position of each of the heat exchange passage 110 in the inlet chamber 120 and the discharge chamber 130 In other words, the pressure drop and the positional relationship between the outlet and the inlet may be a dominant factor to the flow of the heat medium rather than a difference between the conditions and the like encountered in the adjacent heat exchange passage 110. 110) almost constant heating of the medium.

At this time, the length of the blade 220 is defined so that the gap between the end of the blade 220 provided in the scraper 200 and the inner surface of the heat exchange passage 110 is maintained between 0.1mm and 0.4mm. .

Here, the drive unit 170 is operated so that the scraper 200 is rotated at 200 ~ 450rpm, heat exchange is carried out while the heat medium passes through the heat exchange passage 110 is discharged to the discharge chamber 130.

On the other hand, the heat medium flows between the scraper 200 and the inner surface of the heat exchange passage 110, and as the scraper 200 rotates, the heat medium is guided toward the inner surface of the heat exchange passage 110, Guided to discharge chamber 130.

At this time, the sharper the shape of the end of the blade 220 of the scraper 200 can be rotated while reducing the dry out point of the inner surface of the heat exchange passage 110, the heat exchange passage 110 of the blade end The portion corresponding to is preferably about 0.1 mm, but is not limited or restricted now.

Therefore, the heat transfer is promoted while the thin liquid film of the heat medium is continuously formed and destroyed by the shape of the end of the blade 220 in contact with the heat exchange passage 110, and the compression is performed on the curved surface of the front surface of the blade 220. Partial vortex generated when the heat medium is decompressed at the rear side, the supercooling is eliminated, the phase change is promoted, ice crystals are generated, and the supercooling degree is lowered, enabling efficient heat exchange.

In general, the cause of the overload of the ice making device is that the gap between the blade 220 and the heat exchange passage 110 is increased, so that the supercooling degree is increased, thereby causing partial freezing and the scraper to shake off the freezing portion. Although the overload may appear in the 200, in spite of the relatively low rotational speed of the scraper 200 described above, by maintaining a gap between the scraper 200 and the inner surface of the heat exchange passage 110 to prevent excessive supercooling and In addition, there is an advantage that the stable operation is possible by effectively suppressing the phase change of the heat medium adhered to the inner surface of the heat exchange passage.

The scraper 200 inserted into the plurality of heat exchange passages 110 to prevent aggregation or clogging due to interference between the heat mediums discharged from the adjacent heat exchange passages 110 to the discharge chamber 130. It is preferable that the scraper inserted into the adjacent heat exchange passage 110 and the rotation direction are arranged to be driven in reverse.

Due to the characteristics of the above-described structure, the power required in the ice making apparatus according to the embodiment of the present invention is minimized, and it has been shown that an initial overload phenomenon in the existing ice making apparatus does not appear, and the heat transfer efficiency is increased. These results are shown in FIGS. 7 and 8. FIG. 7 is a measurement graph illustrating a change in scraper power during an ice making operation of a conventional ice making device, and FIG. 8 is a change in scraper power during an ice making operation of an ice making device according to an embodiment of the present invention. It is a graph.

As shown in the drawing, in the ice making apparatus according to an embodiment of the present invention, the initial overload phenomenon of the scraper 200 appears to be relatively smaller than that of the existing ice making apparatus based on the change in power.

In the above-described shape of the blade 220 of the scraper 200, that is, the front surface is curved with respect to the rotational direction and the rear surface is inclined, the narrow surface is maintained and the scraper 200 is stopped and driven. Since the positional deviation of the scraper 200 is driven and converges from the heat exchange passage 110 to the center during driving, the heat exchange passage 110 horizontally parallels the gravity direction, as well as the structure of the ice maker. can do.

Therefore, the ice making apparatus according to the embodiment of the present invention may be disposed horizontally with respect to the gravity direction. In other words, the heat medium is moved from the inlet chamber 120 to the discharge chamber 130 as the scraper 200 rotates, so that the heat exchange passage 110 is horizontal to the direction of gravity, ie, the ground surface. It is provided in parallel with the discharge chamber 130, the inlet chamber 120 and the drive unit 170 is provided on the side of the heat exchanger 100 to flow the heat medium in a large capacity, The effects of gravity can be minimized.

In addition, by keeping the ice making machine horizontal, the refrigerant boiling outside the heat exchange passage 110 can be controlled to be stably operated in the nuclear boiling region, thereby improving heat transfer efficiency, and increasing the driving unit 170. Maintenance is advantageous in comparison with the case in which it is arranged horizontally and vertically, and the heat exchange passage 110 may have a relatively long length, so that a large amount of heat exchange may be performed according to the strength of the driving unit 170. There is a possible advantage.

Here, the ice making apparatus according to an embodiment of the present invention suggests that the scraper 200 extends to both the discharge chamber 130 and the inflow chamber 120, so that the scraper 200 is the heat medium. It has been shown to have a stirring action for, but is not limited or limited thereto, and FIGS. 3 and 4 are provided to explain this in more detail.

3 is a partial cross-sectional view showing a modified part of the ice making device shown in Figure 1, Figure 4 is a cross-sectional view taken along the line II-II of FIG. For reference, descriptions of components similar or identical to those of FIGS. 1 to 2 will be omitted for convenience of description.

As shown therein, the ice making apparatus further includes a stirring unit 400.

The stirring unit 400 is disposed in the discharge chamber 130, is provided with a plurality of paddles formed radially, and is provided in a substantially similar shape to the propeller, but is not limited thereto.

At this time, the stirring unit 400 is provided to suppress the clogging phenomenon due to phase separation of the heat medium by stirring the heat medium discharged from the heat exchange passage 110 while rotating in the discharge chamber (130).

The heat medium discharged from the heat exchange passage 110 is aggregated or clogged in the heat exchange passage 110 in the form of an ice slurry, but the stirring unit 400 circulates the heat medium in the direction of the discharge port 135. There is an advantage of guiding to suppress clogging or aggregation.

The ice making apparatus according to another embodiment of the present invention will be described with reference to FIGS. 5 to 6 as follows. 5 is a cross-sectional view showing a cross-section of another ice making apparatus according to another embodiment of the present invention, Figure 6 is a cross-sectional view taken along the line III-III.

As shown in the drawing, the ice making device includes a heat exchanger 100, a heat exchange passage 110, an inflow chamber 120, a discharge chamber 130, a scraper 200, a drive unit 170, and a support member 115. And a guide plate 300. For convenience of description, descriptions of the same or similar structures as those described with reference to FIGS. 1 to 4 will be omitted.

The guide plate 300 is formed in a flat plate shape is disposed in the discharge chamber 130, at a predetermined angle in one direction so that the heat medium is guided in the direction of the discharge port 135 with respect to the heat exchange passage 110. It is provided in an inclined state.

At this time, a portion of the scraper 200 extending to the discharge chamber 130 is provided to pass through the guide plate 300, the guide plate 300 through the structure to the outside of the scraper 200 The heat medium, that is, converted to ice slurry, is condensed on the surface of the scraper 200 to be separated from the scraper 200 to guide in the direction of the outlet 135.

In the discharge chamber 130, since the ice particles contained in the heat medium have increased through the heat exchange passage 110, the circulation is relatively slowed, but the guide plate 300 which induces flow to the discharge hole 135 and Through the role of the flow path formed by the scraper 200 does not extend to induce the flow of the heat medium and the stirring of the flow of the heat medium passing through each heat exchange passage 110 and the extended scraper 200 The stagnation prevention role combines the heat medium, that is, the ice slurry, which is heat-exchanged, to the outlet 135 without clogging.

At this time, if the capacity of the ice making device increases, the number of the heat exchange passages 110 may be about 200 or more, but it may be divided into several groups so as to have a passage space for smooth flow between the groups.

In addition, the discharge port 135 may be provided at an upper portion of the discharge chamber 130 so that the thermal medium can be easily discharged to the discharge hole 135 by using the buoyancy of the thermal medium.

A plurality of inlets 125 may be formed in the inlet chamber 120, and a plurality of outlets 135 may also be formed similarly to the inlets 125.

At this time, the inlet 125 is disposed in a position or radially symmetrical with respect to the inside of the inlet chamber 120 to control the flow of the heat medium flowing into the inlet chamber 120. Accordingly, by optimizing the arrangement of the inlet port 125, the difference in flow characteristics of the heat medium due to the relative position of the heat exchange passage 110 in the inlet chamber 120 can be reduced to the maximum.

In addition, the heat medium flows directly into the inflow chamber 120 without passing through a separate distribution device, is stirred by the scraper 200 in the inflow chamber 120, homogenized, and becomes a flow state under the same conditions. By being circulated to 110, there is an advantage that the discharge chamber 130 can be discharged in the same condition as possible.

Here, the ice making apparatus may further include a bypass pipe 119 which connects the discharge chamber 130 and the inflow chamber 120 to each other and is distinguished from the heat exchange passage 110.

The bypass pipe 119 is the inlet when the amount of the heat medium flowing into the inlet chamber 120 is relatively sharply increased or the flow of the heat medium inside the heat exchange passage 110 in part is not smooth, It is provided to move the heat medium of the chamber 120 to the discharge chamber 130, and may be provided with a valve (not shown) for opening if necessary.

The support member 115 serves to support the heat exchange passage 110, and is disposed at a plurality of 500 to 900 mm intervals along the length of the heat exchange passage 110 to prevent sagging of the heat exchange passage 110. The vibration of the heat exchange passage 110 may be suppressed when the scraper 200 is driven.

At this time, the support member 115 is to be in close contact with the gap in the heat exchange passage 110 to prevent breakage or release of the coupling due to the vibration characteristics between the products due to the vibration of the heat exchange passage 110. It is preferably provided, it is provided with a plastic member for the protection of the heat exchange passage.

On the other hand, the ice making apparatus according to the present invention has a small gap between the blade 220 end of the scraper 200 and the inner surface of the heat exchange passage 110 and the front surface of the blade 220 is formed in a curved surface, the scraper When the 200 is rotated, the scraper 200 pushes the heat medium to be adjacent to the inner surface of the heat exchange passage 110 while the scraper 200 converges to the center of the heat exchange passage 110.

Accordingly, the scraper 200 that has sunk downward due to the influence of gravity at the time of converging converges to the center of the heat exchange passage 110 so that the longitudinal movement distance of the scraper 200 becomes very small, thereby generating vibration due to driving. This is minimized. In addition, even when a force is applied to the scraper 200 due to abnormal clogging of the heat exchange passage 110, the heat exchange passage 110 outside the scraper 200 is fixed by the support member 115, thereby causing vibration. Vibration is absorbed due to the elasticity of the plastic material, thereby reducing the expansion of vibration to other parts.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

100: heat exchanger 110: heat exchange path
120: inlet chamber 125: inlet
130: discharge chamber 135: discharge port
170: drive unit 200: scraper
210: rod member 220: blade
300: guide plate 400: stirring unit

Claims (12)

A heat exchanger for absorbing thermal energy while the refrigerant evaporates;
A plurality of heat exchange passages installed horizontally in the heat exchanger to exchange heat with the refrigerant while the heat medium passes therethrough;
An inflow chamber in communication with the heat exchange passage and into which the heat medium flows into the heat exchange passage;
A discharge chamber communicating with the heat exchange passage and discharging the heat medium exchanged with the heat exchange passage;
A rod-shaped rod member and a blade protruding in a spiral shape on the entire outer surface of the rod member, and inserted into the heat exchange passage to move the heat medium from the inlet chamber to the discharge chamber, A scraper extending into at least one of the discharge chambers; And
A driving unit providing a driving force of the scraper;
Ice making device comprising a. delete A heat exchanger for absorbing thermal energy while the refrigerant evaporates;
A plurality of heat exchange passages installed horizontally in the heat exchanger to exchange heat with the refrigerant while the heat medium passes therethrough;
An inflow chamber in communication with the heat exchange passage and into which the heat medium flows into the heat exchange passage;
A discharge chamber communicating with the heat exchange passage and discharging the heat medium exchanged with the heat exchange passage;
A scraper including a rod-shaped rod member and a blade protruding in a spiral shape on the outside of the rod member, the scraper being inserted into the heat exchange passage and rotating to move the heat medium from the inlet chamber to the discharge chamber;
A driving unit providing a driving force of the scraper; And
A stirring unit including a plurality of paddles formed radially and arranged in at least one of the discharge chamber or the inlet chamber to suppress clogging due to phase separation of the heat medium;
Ice making device comprising a. delete A heat exchanger for absorbing thermal energy while the refrigerant evaporates;
A plurality of heat exchange passages installed horizontally in the heat exchanger to exchange heat with the refrigerant while the heat medium passes therethrough;
An inflow chamber in communication with the heat exchange passage and into which the heat medium flows into the heat exchange passage;
A discharge chamber communicating with the heat exchange passage and discharging the heat medium exchanged with the heat exchange passage;
A scraper including a rod-shaped rod member and a blade protruding in a spiral shape on the outside of the rod member, the scraper being inserted into the heat exchange passage and rotating to move the heat medium from the inlet chamber to the discharge chamber; And
A driving unit providing a driving force of the scraper;
/ RTI >
The cross-sectional shape of the blade is provided with one surface is a curved surface, the other side is provided with at least one of a combination of one straight line or a plurality of straight lines,
The scraper is in contact with the bottom surface of the heat exchange passage by gravity when stopped, and converges to the center of the heat exchange passage during the driving, the icemaker maintains a constant gap between the end of the blade and the inner surface of the heat exchange passage. delete delete delete delete A heat exchanger for absorbing thermal energy while the refrigerant evaporates;
A plurality of heat exchange passages installed horizontally in the heat exchanger to exchange heat with the refrigerant while the heat medium passes therethrough;
An inflow chamber in communication with the heat exchange passage and into which the heat medium flows into the heat exchange passage;
A discharge chamber communicating with the heat exchange passage and discharging the heat medium exchanged with the heat exchange passage;
A scraper including a rod-shaped rod member and a blade protruding in a spiral shape on the outside of the rod member, the scraper being inserted into the heat exchange passage and rotating to move the heat medium from the inlet chamber to the discharge chamber; And
A driving unit providing a driving force of the scraper;
/ RTI >
The inlet chamber communicates with the outside to form one or more inlets for introducing the heat medium therein, and when the inlets are formed in plurality, the plurality of inlets are arranged in a symmetrical direction with respect to the inlet chamber. An ice making device disposed radially. A heat exchanger for absorbing thermal energy while the refrigerant evaporates;
A plurality of heat exchange passages installed horizontally in the heat exchanger to exchange heat with the refrigerant while the heat medium passes therethrough;
An inflow chamber in communication with the heat exchange passage and into which the heat medium flows into the heat exchange passage;
A discharge chamber communicating with the heat exchange passage and discharging the heat medium exchanged with the heat exchange passage;
A plurality of scrapers including a rod-shaped rod member and a blade protruding in a spiral shape on the outside of the rod member and inserted into the heat exchange passage to move the heat medium from the inlet chamber to the discharge chamber; And
A driving unit providing a driving force of the plurality of scrapers;
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Some of the scrapers located at a portion corresponding to the central portion of the flow of the heat medium of the plurality of scrapers are not formed to extend into the inlet chamber and the discharge chamber, the remaining scrapers other than the partial scraper is in the inlet chamber or the discharge chamber An ice making device extending into at least one interior. A heat exchanger for absorbing thermal energy while the refrigerant evaporates;
A plurality of heat exchange passages installed horizontally in the heat exchanger to exchange heat with the refrigerant while the heat medium passes therethrough;
An inflow chamber in communication with the heat exchange passage and into which the heat medium flows into the heat exchange passage;
A discharge chamber communicating with the heat exchange passage and discharging the heat medium exchanged with the heat exchange passage;
A scraper including a rod-shaped rod member and a blade protruding in a spiral shape on the outside of the rod member, the scraper being inserted into the heat exchange passage and rotating to move the heat medium from the inlet chamber to the discharge chamber;
A driving unit providing a driving force of the scraper; And
Bypass pipe connecting the discharge chamber and the inlet chamber;
Ice making device comprising a.

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