JP6004906B2 - Evaporator with cool storage function - Google Patents

Description

  The present invention relates to an evaporator with a cold storage function capable of storing cold heat.

  Conventionally, for example, a refrigeration cycle including a refrigerant compressor driven by an engine has been used for an air conditioner for a vehicle, and an evaporator of the refrigeration cycle is generally used as an air cooler.

  In recent years, vehicles equipped with a so-called idling stop function that automatically stops an engine from the viewpoint of improving fuel efficiency and reducing environmental load have become widespread. When the engine is stopped, the refrigerant compressor is also stopped, so that the cooling performance of the passenger compartment cannot be ensured. As a result, the engine is frequently restarted, and the effect of the idling stop function cannot be sufficiently obtained.

  Therefore, for example, as disclosed in Patent Documents 1 and 2, it is considered that an evaporator has a cold storage function to suppress an increase in cold air temperature during idling stop.

  The evaporator of patent document 1 is a tube and fin type heat exchanger provided with the core which consists of a some tube and fin, and a pair of header tank connected to the edge part of a tube. The inside of the header tank is partitioned into two in the flow direction of the external air, and the refrigerant flows in the space on the upstream side of the external air, while the regenerator material is sealed in the space on the downstream side. The tube is composed of a refrigerant circulation tube that communicates with a portion where the refrigerant circulates inside the header tank, and a cool storage material-enclosed tube that communicates with a portion that encloses the cool storage material.

JP 2011-133126 A

  By the way, in the evaporator with a cool storage function of patent document 1, in the situation where the cool storage part is not storing cold heat, the cold heat of the cold air cooled in the external air flow direction upstream side (windward side) of the evaporator is used as the cool storage material in the cool storage part. I will be taken away. In particular, in Patent Document 1, a cold storage material enclosing tube is disposed on the entire downstream side (downward side) of the flow direction of the external air, and the entire leeward side of the evaporator serves as a cold storage unit. The whole amount passes through the cold storage part. Therefore, there is a concern about a decrease in cooling performance.

  Moreover, in patent document 1, since the cool storage material is enclosed with the whole leeward side, an evaporator will be enlarged correspondingly. Further, depending on the air conditioner, there is a case where the regenerator material is not necessary for the entire leeward side, and in this case, the cost is increased.

  The present invention has been made in view of the above points, and the object of the present invention is to suppress a decrease in cooling performance due to the provision of the cold storage unit, and to minimize the necessary amount without unnecessarily increasing the cold storage unit. The purpose is to reduce the cost by making it possible to reduce the size.

  In order to achieve the above object, according to the present invention, when the refrigerant discharge amount of the refrigerant compressor is decreased, no cool storage material is provided on the leeward side of the portion where the rising speed of the surface temperature is slow, and the surface temperature is increased. A cold storage material was provided on the leeward side of the fast part.

A first aspect of the invention is an evaporator with a cold storage function provided with a cold storage unit for storing cold energy while the refrigerant discharged from the refrigerant compressor is supplied via an expansion valve.
When the refrigerant discharge amount of the refrigerant compressor is reduced, the first portion where the rising speed of the surface temperature is the first speed and the second speed rising at a second speed slower than the first speed. 2 parts,
The cold storage unit is arranged on the leeward side of the first part and is not arranged on the leeward side of the second part.

  According to this configuration, for example, when the refrigerant compressor is stopped and the refrigerant discharge amount is reduced, the surface temperature of the evaporator is such that the rising speed of the first part is high and the rising speed of the second part is slow. Become. Since the cold storage unit is arranged on the leeward side of the first part, the cold storage temperature can be kept low by the cold storage unit even if the surface temperature of the first part rises quickly. Even when the machine stops, comfort is maintained well.

  On the other hand, at normal times when the refrigerant discharge amount of the refrigerant compressor is not decreasing, the cold storage part is not arranged on the leeward side of the second part, so that air passing through the second part does not pass through the cold storage part. Therefore, since it becomes possible to supply low temperature air indoors, high cooling performance is ensured.

  And since a cool storage part is not arrange | positioned in the leeward side of a 2nd part, it becomes possible to make the magnitude | size of a cool storage part small, without almost affecting a comfort as mentioned above.

According to a second invention, in the first invention,
It has multiple paths that continue in the flow direction of the refrigerant,
The second part is characterized by being the most upstream path in the refrigerant flow direction.

  According to this configuration, the refrigerant discharged from the refrigerant compressor circulates through the path on the downstream side after flowing through the most upstream path in the refrigerant flow direction of the evaporator. Since the most upstream path has a high liquid phase ratio of the refrigerant, even if the refrigerant discharge amount of the refrigerant compressor decreases, there is a cold storage effect due to the latent heat of vaporization of the liquid refrigerant. In other words, the speed of the surface temperature of the most upstream path is slower than that of the other paths, so that the cool storage unit is not arranged on the leeward side with this most upstream path as the second part. The comfort is well maintained.

According to a third invention, in the first invention,
It has a tube that extends in the vertical direction and through which refrigerant flows,
The second part is a lower part of the tube.

  According to this configuration, the dew condensation water generated on the surface of the tube during cooling flows down to the lower portion on the surface of the tube because the tube extends in the vertical direction. Since the condensed water is cooled, the rising speed of the surface temperature of the lower portion of the tube is slowed by the cold heat of the condensed water even if the refrigerant discharge amount is reduced. By making the lower part of this tube the second part and not disposing the cold storage part on the leeward side, the comfort during cooling is maintained well.

According to a fourth invention, in the first invention,
A plurality of paths connected in the flow direction of the refrigerant;
It has a tube that extends in the vertical direction and through which refrigerant flows,
The second part is a path in the most upstream flow direction of the refrigerant and a lower part of the tube.

  According to this structure, the comfort at the time of cooling is maintained favorable by not arrange | positioning a cool storage part to the leeward side of the uppermost path | pass and the lower part of a tube.

According to a fifth invention, in any one of the first to fourth inventions,
The cold storage unit is separate from the main body portion of the evaporator and is attached to the main body portion.

  According to this configuration, since the cold storage unit is a separate body, the size of the cold storage unit can be freely set without affecting the flow pattern of the refrigerant in the main body portion of the evaporator, the drainage structure of condensed water, and the like. It becomes possible.

A sixth invention is the invention according to any one of the first to fourth inventions,
The cold storage unit is incorporated in a main body portion of the evaporator.

  According to this configuration, when the evaporator is accommodated in, for example, the air conditioning casing, the cold storage unit can be accommodated together with the main body portion of the evaporator, so that the workability at the time of manufacturing the air conditioner is improved.

  According to the first invention, the cold storage unit is arranged on the leeward side of the first part where the rising speed of the surface temperature is high when the refrigerant discharge amount is reduced, and the leeward side of the second part where the rising speed is slow. Therefore, it is possible to suppress the reduction in cooling performance due to the provision of the cool storage unit, and to reduce the cost by reducing the size to the minimum necessary without unnecessarily increasing the cool storage unit.

  According to the second aspect of the present invention, the upstream flow path in the refrigerant flow direction has a slow rise in surface temperature, and the cool storage part is not disposed on the leeward side of the upstream flow path. The effect becomes even more remarkable.

  According to the third invention, the rising speed of the surface temperature of the lower part of the tube extending in the up-down direction is slow, and the cold storage part is not disposed on the leeward side of the lower part of the tube. The effect of the present invention becomes even more remarkable.

  According to the fourth aspect of the invention, since the cold storage unit is not arranged on the leeward side of the lowermost portion of the path and the uppermost stream in the refrigerant flow direction, the effect of the first aspect of the invention becomes even more remarkable. .

  According to the fifth aspect of the invention, since the cold storage unit is separated from the evaporator main body, the size of the cold storage unit is not affected without affecting the flow pattern of the refrigerant in the main body of the evaporator or the drainage structure of condensed water. Can be set freely.

  According to the sixth aspect of the invention, since the cold storage unit is incorporated in the main body portion of the evaporator, workability at the time of manufacturing the air conditioner can be improved.

It is the perspective view which looked at the evaporator with a cool storage function concerning Embodiment 1 from the leeward side. It is the II-II sectional view taken on the line of FIG. It is the figure which showed typically the evaporator with a cool storage function which concerns on Embodiment 1. FIG. FIG. 3 is a view corresponding to FIG. 1 of an evaporator with a cold storage function according to a second embodiment. FIG. 6 is a view corresponding to FIG. 1 of an evaporator with a cold storage function according to a third embodiment. FIG. 6 is a view corresponding to FIG. 1 of an evaporator with a cold storage function according to a fourth embodiment. FIG. 6 is a view corresponding to FIG. 1 of an evaporator with a cold storage function according to a fifth embodiment. FIG. 9 is a view corresponding to FIG. 1 of an evaporator with a cold storage function according to a sixth embodiment. FIG. 9 is a view corresponding to FIG. 3 of an evaporator with a cold storage function according to a seventh embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature, and is not intended to limit the present invention, its application, or its use.

(Embodiment 1)
FIG. 1: is the perspective view which looked at the evaporator 1 with a cool storage function which concerns on Embodiment 1 of this invention from the leeward side (downstream direction of the flow direction of external air). FIG. 2 is a diagram showing a horizontal section of the upper header tank 3 of the evaporator 1. Although not shown, the evaporator 1 is an element of a refrigeration cycle of a vehicle air conditioner. In addition to the evaporator 1, the refrigeration cycle includes a refrigerant compressor that compresses refrigerant as a heat exchange medium, a condenser, and an expansion valve. These devices are connected by a refrigerant pipe so that the refrigerant circulates. . Since the refrigerant compressor is driven by the engine of the vehicle, when the engine stops, the refrigerant discharge amount from the refrigerant compressor decreases and becomes zero.

  The vehicle is also equipped with a so-called idling stop device configured to automatically stop idling of the engine when the vehicle is stopped and when a predetermined condition for engine automatic stop is satisfied. The configuration of the idling stop device is well known in the art and will not be described. The idling stop device permits automatic stop of idling when the vehicle control device determines that the cooling performance and heating performance required by the occupant can be secured, for example, even while the air conditioner is in operation. When it is determined that the required cooling performance or heating performance cannot be ensured, automatic idling is prohibited.

  The evaporator 1 is accommodated in a casing 100 (shown in phantom only in FIG. 1) together with, for example, a heat exchanger for heating. The casing 100 can also accommodate an air mix damper, a blowing direction switching damper, and the like.

  The evaporator 1 includes a core 2, an upper header tank 3, and a lower header tank 4. The core 2 includes a plurality of leeward side tubes 21 and a windward side tube 22 (schematically shown in FIG. 3) shown in FIG. 2, a plurality of fins 23 shown in FIG. 1, and a pair of end plates 24. Yes.

  The leeward side tube 21 is disposed downstream of the evaporator 1 in the direction of external air flow (the direction indicated by the arrow X in each figure), and the windward side tube 22 is disposed upstream of the evaporator 1 in the direction of external airflow. The evaporator 1 has a double-row structure in which two rows of tubes 21 and 22 are arranged in the flow direction of external air.

  The leeward side tube 21 and the leeward side tube 22 are both flat tubes that extend in the vertical direction and have a long cross-sectional shape in the flow direction of the external air. The leeward side tube 21 is disposed at a predetermined interval in the width direction of the evaporator 1 (left and right direction in FIG. 1), and the fins 23 are disposed between the adjacent leeward side tubes 21. The leeward side tube 21 is divided into two tube groups on the left and right by the arrangement of the second partition plate 32 of the upper header tank 3 to be described later, and the tube 21a on the right side of the second partition plate 32 has a cold storage material. The refrigerant is circulated through the filled tube 21b on the left side of the second partition plate 32. The path formed by the tube 21b is the most upstream path 101 (shown in FIGS. 2 and 3) located at the most upstream in the refrigerant flow direction. The tube 21a and the tube 21b are the same tube with the same cross-sectional shape, outer shape, length, and the like.

  In addition, as a cool storage material, what is used conventionally can be used, and a kind is not specifically limited. Further, the upper end portion and the lower end portion of the tube 21a may be closed to enclose the regenerator material in the tube 21a. The upper end portion and the lower end portion of the tube 21a may not be closed, and the tubes 21a in the header tanks 3 and 4 may be closed. You may fill the space which connects with a cool storage material.

  In FIG. 3, a portion surrounded by a thick line represents the cold storage unit 110 including the tube 21 a filled with the cold storage material. When the refrigerant discharge amount of the refrigerant compressor decreases, the cold storage unit 110 is disposed only on the leeward side of the portion where the rising speed of the surface temperature in the evaporator 1 is fast, and the leeward side of the portion where the rising speed of the surface temperature is slow Is not arranged. Since the cool storage unit 110 is configured by the tube 21a, the cool storage unit 110 can be incorporated into the main body portion of the evaporator 1, and the cool storage unit 110 does not protrude from the main body portion.

  Moreover, since the windward side tube 22 is arrange | positioned similarly to the leeward side tube 21, when it sees from the flow direction of external air, the leeward side tube 21 and the windward side tube 22 will mutually overlap. For this reason, for example, when the windward side tube 22 is viewed from the upstream side in the flow direction of the external air, the leeward side tube 21 is hardly visible.

  As shown in FIG. 2, the windward tube 22 is divided into a left tube 22 group and a right tube 22 group by a third partition plate 33. A path formed by the left tube group 22 is an intermediate path 102 (shown in FIG. 2) communicating with the downstream side of the most upstream path 101 in the refrigerant flow direction. The path formed by the two groups of right tubes is the most downstream path 103 (shown in FIG. 2) communicating with the intermediate path 102 on the downstream side in the refrigerant flow direction.

  The fins 23 are corrugated fins extending in the vertical direction. The fins 23 are continuous from the leeward side tube 21 to the windward side tube 22 of the evaporator 1. That is, the core 2 is configured such that a plurality of the leeward side tubes 21, the windward side tubes 22, and the fins 23 are alternately arranged in the width direction of the evaporator 1.

  The end plate 24 is disposed so as to cover the fin 23 at the outer end of the core 2 from the outside.

  The upper header tank 3 is disposed at the upper ends of the tubes 21 and 22 and has a cylindrical shape extending in the width direction of the evaporator 1 (the arrangement direction of the tubes 21 and 22 and the fins 23). Inside the upper header tank 3, a first partition plate 31 for partitioning the internal space of the upper header tank 3 into a leeward space R on the downstream side in the flow direction of the external air and an upstream windward space S on the upstream side; A second partition plate 32 for partitioning the leeward side space R into a left side space R2 on the left side of the evaporator 1 and a right side space R1; a left side space S2 on the left side of the evaporator 1 and a right side space S1 on the right side of the evaporator 1; And a third partition plate 33 for partitioning. The first to third partition plates 31 to 33 become partition portions of the upper header tank 3.

  To the left space R2 of the leeward side space R, the upper end portion of the tube 21b of the most upstream path 101 through which the refrigerant circulates is connected. In addition, a tube 21a filled with a cold storage material is connected to the right space R1 of the leeward space R. In addition, the upper end portion of the windward tube 22 is connected to the windward space S of the upper header tank 3.

  As shown in FIG. 1, a supply pipe 50 that supplies refrigerant to the upper header tank 3 is provided on the leeward side of the right end surface of the upper header tank 3. It is connected to the right space R1 of the side space R. A discharge pipe 51 for discharging the refrigerant in the upper header tank 3 is provided on the windward side of the right end surface of the upper header tank 3, and the discharge pipe 51 is a right space of the windward space S of the upper header tank 3. Connected to S1. Therefore, the supply pipe 50 and the discharge pipe 51 are connected to the header tank 3 from the same side surface of the evaporator 1 and are adjacent to each other.

  Further, a bypass pipe 39 constituting a bypass passage is provided in the right space R1 of the leeward space R of the upper header tank 3. The bypass pipe 39 is for flowing the refrigerant supplied from the supply pipe 50 to the left space R2 by bypassing the right space R1. The upstream side of the bypass pipe 39 is connected to the supply pipe 50. The downstream side of the bypass pipe 39 penetrates the second partition plate 32 and is connected to the left space R2. Accordingly, the supply pipe 50 communicates with the left space R2 via the bypass pipe 39.

  In addition, the left side space R2 of the leeward side space R and the left side space S2 of the leeward side space S communicate with the portion of the first partition plate 31 of the upper header tank 3 on the left side of the second partition plate 32. A hole 31a is formed.

  The lower header tank 4 is disposed at the lower end of the tubes 21 and 22 and has a cylindrical shape extending in the width direction of the evaporator 1. Inside the lower header tank 4 is a first partition plate for partitioning the internal space of the lower header tank 4 into a leeward space T on the downstream side in the flow direction of the external air and an upwind space U on the upstream side. 41 and a second partition plate 42 for partitioning the leeward space T into a left space T2 on the left side of the evaporator 1 and a right space T1 on the right side. The first and second partition plates 41 and 42 serve as partition portions for the lower header tank 4.

  Of the leeward side tube 21, a lower end portion of the tube 21 b through which the refrigerant flows is connected to the left side space T <b> 2 of the leeward side space T. A tube 21a filled with a cold storage material is connected to the right space T1 of the leeward space T. Further, the lower end portion of the windward side tube 22 is connected to the windward side space U of the lower header tank 4.

  Further, as shown in FIG. 3, the left space T2 and the windward space U of the leeward space T are communicated with the portion of the first header 41 of the lower header tank 4 on the left side of the second partition 42. The communication hole 41a for making it form is formed.

  Next, the operation of the evaporator 1 configured as described above will be described. When the engine is in an operating state and the refrigerant compressor is operating, the refrigerant depressurized via the expansion valve is supplied from the supply pipe 50 to the leeward space of the upper header tank 3 as indicated by the arrow A in FIG. It flows into the bypass pipe 39 in the right space R1 of the R, and flows through the bypass pipe 39 to the left as shown by the arrow B.

  The refrigerant that has flowed through the bypass pipe 39 flows into the left space R2 of the leeward space R, and then divides and flows into the leeward tube 21b (the most upstream path 101) as indicated by an arrow C1, and the leeward tube 21b is passed through the It flows and flows into the left space T2 of the leeward space T of the lower header tank 4, and flows into the left space S2 of the windward space S from the communication hole 31a as indicated by an arrow C2. The refrigerant that has flowed into the left space T2 of the leeward space T of the lower header tank 4 flows into the windward space U from the communication hole 41a of the lower header tank 3 as indicated by an arrow D. On the other hand, the refrigerant that has flowed into the left space S2 of the windward space S of the upper header tank 3 flows into the windward tube 22 (the intermediate path 102 shown in FIG. 2) connected to the left space S2, as indicated by an arrow E. Then, it flows through the windward side tube 22 and flows into the windward side space U of the lower header tank 4. The refrigerant flowing into the windward space U of the lower header tank 4 is connected to the right space S1 of the windward space S of the upper header tank 3 as shown by the arrow F (the most downstream side shown in FIG. 2). Flows into the path 103), flows through the windward tube 22 and flows into the right space S1 of the windward space S of the upper header tank 3. The refrigerant that has flowed into the right space S1 of the windward space S of the upper header tank 3 is discharged from the discharge pipe 51 to the outside as indicated by an arrow G.

  In this embodiment, the refrigerant in the left space R2 of the leeward space R of the upper header tank 3 is caused to flow through the windward tube 22 overlapping the windward side of the tube 21a filled with the cold storage material, as indicated by an arrow C2. ing. Thereby, the flow volume of the refrigerant | coolant which distribute | circulates to the tube 22 located in the external air flow direction upstream of the tube 21a with which the cool storage material was filled can be increased.

  While the refrigerant flows through the leeward side tube 21b and the leeward side tube 22, the refrigerant exchanges heat with the external air to cool the external air, and cools the cold storage material in the leeward side tube 21a to store the cold energy in the cold storage material. It is done. At this time, since the cool air cooled by passing through the windward tube 22 contacts the leeward tube 21a, the cool storage time for the cool storage material is shortened. Furthermore, since the leeward side tube 21b through which the refrigerant flows is adjacent to the left side of the leeward side tube 21a, the cold heat of the leeward side tube 21b is easily transmitted to the regenerator material of the leeward side tube 21a. Cold storage time is shortened.

  Until the cool storage material is sufficiently stored, when the cold air that has been cooled by passing between the windward side tubes 22 passes between the leeward side tubes 21a, heat is exchanged with the cold storage material, so that the temperature of the cold wind rises. Will do. In this embodiment, since the cool storage unit 110 is not arranged on the leeward side of the tube 21 b constituting the most upstream path 101, the cold energy of the cold air passing between the tubes 21 b of the most upstream path 101 is taken away by the cool storage unit 110. Absent. Moreover, since the refrigerant in the tube 21b constituting the most upstream path 101 has a high liquid phase rate, the latent heat of vaporization is large, and the temperature of the cold air passing between the tubes 21b is further lowered. Therefore, even if the cold storage unit 110 is provided, high maximum cooling performance can be obtained.

  When the idling of the engine is automatically stopped, the refrigerant discharge amount from the refrigerant compressor becomes zero, so the refrigerant inflow amount to the evaporator 1 becomes zero. Even if the amount of refrigerant flowing into the evaporator 1 becomes 0, the liquid phase ratio of the refrigerant inside the tube 21b constituting the most upstream path 101 is high for a while, so the most upstream path 101 is constituted. The tube 21b has a cold storage effect due to the latent heat of vaporization of the liquid refrigerant. On the other hand, the refrigerant in the tube 22 constituting the most downstream path 103 downstream of the most upstream path 101 has a lower liquid phase ratio than the refrigerant in the tube 21b constituting the most upstream path 101 and is almost in a gas state. Therefore, the cold storage effect due to latent heat of vaporization is lower than that of the tube 21b constituting the most upstream path 101. Therefore, the rising speed of the surface temperature of the tube 21b constituting the most upstream path 101 is slower than the rising speed of the surface temperature of the tube 22 constituting the most downstream path 103. In this embodiment, the most upstream path is constituted. The cool storage unit 110 is arranged only on the leeward side of the tube 22 constituting the most downstream path 103 without arranging the cool storage unit 110 on the leeward side of the tube 21b.

  The tube 22 constituting the most downstream path 103 corresponds to the first part of the present invention, and the rising speed of the surface temperature that rises when the refrigerant discharge amount of the refrigerant compressor decreases is the first speed. That's it. On the other hand, the tube 21b constituting the most upstream path 101 corresponds to the second part of the present invention, and the rising speed of the surface temperature that rises when the refrigerant discharge amount of the refrigerant compressor decreases is the second. Is the speed.

  Since the cold storage unit 110 is disposed on the leeward side of the tube 22 constituting the most downstream path 103, even if the surface temperature of the tube 22 constituting the most downstream path 103 rises quickly, the cold storage unit 110 is stored in the cold storage unit 110. Cold heat is released and the cold air temperature can be kept low. Therefore, even when the refrigerant compressor is stopped, the comfort is maintained well.

  In this embodiment, in order to improve the cold storage performance, the number of the leeward tubes 21a filled with the cold storage material may be increased. Specifically, the second partition plate 32 of the upper header tank 3 is moved to the left side. In addition, the second partition plate 42 of the lower header tank 4 is similarly moved to the left side. In the case of reducing the cold storage performance, the second partition plates 32 and 42 may be moved to the right side.

  On the other hand, in order to improve the maximum cooling performance, the number of the leeward side tubes 21b through which the refrigerant flows may be increased. Specifically, the second partition plate 32 of the upper header tank 3 is moved to the right side, and Similarly, the second partition plate 42 of the side header tank 4 is moved to the right side. In order to reduce the maximum cooling performance, the second partition plates 32 and 42 may be moved to the left side.

  When changing the cold storage performance or maximum cooling performance, there is no major structural change in the upper header tank 3 or lower header tank 4, and there is no need to change the number of rows of tubes in the direction of external air flow. It is possible to do it.

  In this embodiment, since the cold storage material is filled in the tube 21a, the fins 23 do not need to be crushed, and the ventilation resistance of the evaporator 1 does not increase in order to provide the cold storage function.

  As described above, according to the evaporator 1 according to the first embodiment, the cool storage unit 110 is placed on the leeward side of the tube 22 of the most downstream path 103 where the surface temperature rises quickly when the refrigerant discharge amount decreases. It arrange | positions and it does not arrange | position on the leeward side of the tube 21b of the uppermost stream path | pass 101 with a slow ascending speed. Thereby, while being able to suppress the cooling performance fall by providing the cool storage part 110, without making the cool storage part 110 unnecessarily large, it can aim at the required minimum magnitude | size and can aim at cost reduction.

  Moreover, since the cool storage part 110 is incorporated in the main body part of the evaporator 1, the cool storage part 110 is accommodated in the main body part of the evaporator 1 (tubes 21 b, 22, header tank 3) when accommodated in the air conditioning casing 100 during manufacture of the air conditioner. , 4, end plates 24, 24, etc.). Therefore, workability at the time of manufacturing the air conditioner is improved.

(Embodiment 2)
FIG. 4 shows an evaporator 1 with a cold storage function according to Embodiment 2 of the present invention. The second embodiment is different from the first embodiment only in the structure of the cold storage unit 110 and the other parts are the same as those in the first embodiment. Therefore, the parts different from the first embodiment will be described below.

  In the first embodiment, the cold storage material is filled in the tube 21a. However, in the second embodiment, the tube 21a is omitted, and some of the fins 23 are replaced with the cold storage material container 109 filled with the cold storage material. Yes. Therefore, the cool storage material containers 109 are arranged in the width direction of the evaporator 1. The cool storage material container 109 extends from the lower surface of the upper header tank 3 to the upper surface of the lower header tank 4. The cool storage unit 110 is configured by a plurality of cool storage material containers 109. Fins 23 are disposed between the cool storage material containers 109 arranged in the width direction of the evaporator 1.

  Similarly to the first embodiment, the evaporator 1 of the second embodiment also arranges the cold storage unit 110 on the leeward side of the tube 22 of the most downstream path 103 where the surface temperature rises quickly when the refrigerant discharge amount decreases, It is not arranged on the leeward side of the tube 21 of the most upstream path 101 having a slow ascent rate.

  Thereby, while being able to suppress the cooling performance fall by providing the cool storage part 110, without making the cool storage part 110 unnecessarily large, it can aim at the required minimum magnitude | size and can aim at cost reduction.

(Embodiment 3)
FIG. 5 shows an evaporator 1 with a cold storage function according to Embodiment 3 of the present invention. The third embodiment is different from the second embodiment only in the structure of the cold storage unit 110 and the other parts are the same as those in the second embodiment. Therefore, the parts different from the second embodiment will be described below.

  In the second embodiment, the cool storage material container 109 has reached the upper surface of the lower header tank 4, but in this third embodiment, the lower side of the cool storage material container 109 is spaced upward from the upper surface of the lower header tank 4.

  When the air is cooled, the condensed water generated on the surfaces of the tubes 21 and 22 flows down to the lower portion of the surfaces of the tubes 21 and 22 because the tubes 21 and 22 extend in the vertical direction. Water is retained in the gap. Since the retained condensed water is cooled, even if the refrigerant discharge amount from the refrigerant compressor is decreased, the rising speed of the surface temperature of the lower part of the tubes 21 and 22 is reduced by the cold heat of the condensed water. , 22 is slower than the upper part (region where water is not retained). The upper part of the windward tube 22 is a first part whose surface temperature rise speed is the first speed. The lower part of the windward tube 22 is a second part in which the rising speed of the surface temperature rises at a second speed that is slower than the first speed.

  By separating the lower side of the cool storage material container 109 upward from the upper surface of the lower header tank 4, the cool storage unit 110 is disposed only on the leeward side of the upper portion of the windward side tube 22, and the lower side portion of the windward side tube 22. Will not be placed on the leeward side. The lower part of the windward side tube 22 is a range of about ¼ to の of the vertical dimension of the tube 22 from the lower end of the tube 22 upward.

  Therefore, in the evaporator 1 according to the third embodiment, the cool storage unit 110 is disposed on the leeward side of the most downstream path 103 where the surface temperature rises quickly when the refrigerant discharge amount is reduced, and on the upper part of the windward side tube 22. Only on the leeward side of the tube 21 of the most upstream path 101 where the rising speed is slow, and not on the lower side portion of the windward side tube 22. Thereby, while being able to suppress the cooling performance fall by providing the cool storage part 110, without making the cool storage part 110 unnecessarily large, it can aim at the required minimum magnitude | size and can aim at cost reduction.

(Embodiment 4)
FIG. 6 shows an evaporator 1 with a cold storage function according to Embodiment 6 of the present invention. This Embodiment 4 differs in the structure of the cool storage part 110 from the said Embodiment 1-3. Hereinafter, a different part from Embodiment 1-3 is demonstrated.

  In the fourth embodiment, the cold storage unit 110 is separated from the main body portion of the evaporator 1 and is attached to the main body portion. The cool storage unit 110 is an integrated unit in which cool storage material containers 109 filled with a cool storage material and fins 108 are alternately arranged. The cold storage unit 110 can be fixed to the end plate 24 and the header tanks 3 and 4 and protrudes from the main body portion of the evaporator 1.

  Similarly to the third embodiment, the cold storage unit 110 is disposed only in the upper portion of the windward tube 22 where the surface temperature rises quickly when the refrigerant discharge amount decreases, and the windward tube 22 with a slow rise rate. The lower part is not arranged.

  Therefore, in the evaporator 1 of Embodiment 4, while being able to suppress the fall of the cooling performance by providing the cool storage part 110, without reducing the cool storage part 110 unnecessarily, it aims at the required minimum magnitude | size and aims at cost reduction. Can do.

  In addition, since the cold storage unit 110 is separated from the main body portion of the evaporator 1, the size of the cold storage unit 110 can be increased without affecting the flow pattern of the refrigerant in the main body portion of the evaporator 1, the drainage structure of condensed water, and the like. It can be set freely.

  In addition, the evaporator 1 that does not require the cold storage unit 110 can be dealt with simply by omitting the cold storage unit 110 without substantially changing the structure of the main body of the evaporator 1.

(Embodiment 5)
FIG. 7 shows an evaporator 1 with a cold storage function according to Embodiment 5 of the present invention. In the fifth embodiment, the structure of the cold storage unit 110 is different from that of the fourth embodiment. Hereinafter, a different part from Embodiment 4 is demonstrated.

  The cold storage unit 110 of the fifth embodiment is narrower than the cold storage unit 110 of the fourth embodiment. And the cool storage part 110 is arrange | positioned only in the leeward side of the tube 22 of the most downstream path | pass 103 whose surface temperature rises quickly, when the refrigerant | coolant discharge amount reduces, and the tube 21b of the most upstream path | pass 101 whose rise speed is slow. It is not arranged on the leeward side.

  Therefore, in the evaporator 1 according to the fifth embodiment, the cool storage unit 110 is disposed on the leeward side of the most downstream path 103 where the surface temperature rises rapidly when the refrigerant discharge amount is reduced, and on the upper part of the upwind tube 22. Only on the leeward side of the tube 21 of the most upstream path 101 where the rising speed is slow, and not on the lower side portion of the windward side tube 22. Thereby, while being able to suppress the cooling performance fall by providing the cool storage part 110, without making the cool storage part 110 unnecessarily large, it can aim at the required minimum magnitude | size and can aim at cost reduction.

(Embodiment 6)
FIG. 8 shows an evaporator 1 with a cold storage function according to Embodiment 6 of the present invention. The evaporator 1 of Embodiment 6 is a serpentine type evaporator in which one tube 20 is bent.

  Fins 23 are disposed between the tubes 20. A supply pipe 50 for supplying a refrigerant is attached to the upstream end of the tube 20. A discharge pipe 51 for discharging the refrigerant is attached to the downstream end of the tube 20.

  Among the tubes 20, the refrigerant that circulates on the side close to the supply pipe 50 has a higher liquid phase ratio than the refrigerant that circulates on the side close to the discharge pipe 51, and therefore has a large latent heat of vaporization. Even when the idling of the engine is automatically stopped, even if the refrigerant inflow amount to the evaporator 1 becomes zero, the liquid phase ratio of the refrigerant on the side close to the supply pipe 50 of the tube 20 is high for a while. There is a cold storage effect due to the latent heat of vaporization of the liquid refrigerant.

  On the other hand, since the refrigerant on the discharge pipe 51 side of the tube 20 has a lower liquid phase ratio than the supply pipe 50 side and is almost in a gas state, the cold storage effect due to latent heat of vaporization is lower than that on the supply pipe 50 side. Therefore, the rising speed of the surface temperature of the tube 20 on the supply pipe 50 side is slower than the rising speed of the surface temperature of the tube 20 on the discharge pipe 51 side, and in this embodiment, the leeward of the tube 20 on the supply pipe 50 side. The cold storage unit 110 is arranged only on the leeward side of the tube 20 on the discharge pipe 51 side without arranging the cold storage unit 110 on the side. The configuration of the cold storage unit 110 is the same as that of the fifth embodiment.

  The discharge pipe 51 side of the tube 20 corresponds to the first part of the present invention, and the rising speed of the surface temperature that rises when the refrigerant discharge amount of the refrigerant compressor decreases is the first speed. is there. On the other hand, the supply pipe 50 side of the tube 20 corresponds to the second part of the present invention, and the rising speed of the surface temperature that rises when the refrigerant discharge amount of the refrigerant compressor decreases is the first speed. The second speed is slower than this.

  As described above, according to the evaporator 1 according to the sixth embodiment, the cool storage unit 110 is placed on the leeward side on the discharge pipe 51 side of the tube 20 whose surface temperature increases rapidly when the refrigerant discharge amount decreases. It arrange | positions and it is made not to arrange | position to the leeward side by the side of the supply pipe | tube 50 of the tube 20 with a slow ascent rate. Thereby, like Embodiment 1, while being able to suppress the fall of the cooling performance by providing the cool storage part 110, without reducing the cool storage part 110 unnecessarily, it aims at the required minimum magnitude | size and aims at cost reduction. Can do.

(Embodiment 7)
FIG. 9 shows an evaporator 1 with a cold storage function according to Embodiment 7 of the present invention. In the seventh embodiment, the refrigerant flow pattern of the evaporator 1 and the arrangement of the cold storage unit 110 are different from those of the first embodiment. Hereinafter, a different part from Embodiment 1 is demonstrated in detail.

  The evaporator 1 according to the seventh embodiment has four paths. That is, the second partition plate 32 in the leeward space R of the upper header tank 3 and the third partition plate 33 in the leeward space S are disposed at the same place in the left-right direction. The first partition plate 31 of the upper header tank 3 is provided with a communication hole 31 a on the left side of the second partition plate 32. Further, the lower header tank 4 is not provided with a partition plate for partitioning in the left-right direction.

  The cold storage unit 110 is disposed on the left side of the second partition plate 32. Further, the cold storage unit 110 is disposed only on the leeward side of the upper portion of the windward side tube 22 and is not disposed on the leeward side of the lower side portion of the windward side tube 22.

  Next, the operation of the evaporator 1 configured as described above will be described. The refrigerant flows from the supply pipe 50 into the right space R1 of the leeward space R of the upper header tank 3 as shown by the arrow A in FIG. 9, and then as shown by the arrow B, the leeward tube 21 communicated with the right space R1. And flows into the leeward space T of the lower header tank 4.

  As indicated by arrow C, the refrigerant flowing into the leeward space T flows through the leeward tube 21 communicating with the left space R2 of the leeward space R of the upper header tank 3 and flows into the left space R2. Thereafter, the air flows into the left space S2 of the windward space S of the upper header tank 3 from the communication hole 31a as shown by the arrow D, and flows through the windward tube 22 communicating with the left space S2 as shown by the arrow E. It flows into the windward space U of the side header tank 4.

  As indicated by the arrow F, the refrigerant flowing into the windward space U flows through the windward tube 22 communicating with the right space S1 of the windward space S of the upper header tank 3 and flows into the right space S1. The refrigerant that has flowed into the right space S1 of the windward space S of the upper header tank 3 is discharged from the discharge pipe 51 to the outside as indicated by an arrow G.

  In the seventh embodiment, as in the third embodiment, the upper portion of the windward tube 22 is a first portion whose surface temperature rise speed is the first speed. The lower part of the windward tube 22 is a second part in which the rising speed of the surface temperature rises at a second speed that is slower than the first speed.

  Also in the seventh embodiment, similarly to the third embodiment, the cold storage unit 110 is disposed only in the upper portion of the windward tube 22 where the surface temperature rises quickly when the refrigerant discharge amount decreases, It is not arranged in the lower part of the slow windward tube 22.

  Therefore, in the evaporator 1 of Embodiment 7, while being able to suppress the fall of the cooling performance by providing the cool storage part 110, without reducing the cool storage part 110 unnecessarily, it aims at the required minimum magnitude | size and aims at cost reduction. Can do.

  Of the leeward side tubes 21, the tube 21 communicating with the right side space R1 of the leeward side space R of the upper header tank 3 constitutes a refrigerant flow most upstream path. By not arranging 110, a high maximum cooling performance can be obtained.

  In addition, the flow pattern of the refrigerant | coolant of the evaporator 1 is not restricted to the above-mentioned pattern, This invention can respond to various flow patterns.

  The above-described embodiment is merely an example in all respects and should not be interpreted in a limited manner. Further, all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

  As described above, the evaporator with a cold storage function according to the present invention can be used, for example, in an air conditioner of an automobile.

DESCRIPTION OF SYMBOLS 1 Evaporator with a cool storage function 2 Core 3 Upper header tank 4 Lower header tank 21 Downwind tube 22 Upwind tube 24 End plate 101 Most upstream path (2nd part)
103 The most downstream path (first part)
110 Cold storage unit

Claims (6)

In the evaporator with a cold storage function, the refrigerant discharged from the refrigerant compressor is supplied through an expansion valve, and has a cold storage unit that stores cold heat.
When the refrigerant discharge amount of the refrigerant compressor is reduced, the first portion where the rising speed of the surface temperature is the first speed and the second speed rising at a second speed slower than the first speed. 2 parts,
The evaporator with a cold storage function, wherein the cold storage unit is arranged on the leeward side of the first part and is not arranged on the leeward side of the second part. In the evaporator with a cool storage function according to claim 1,
It has multiple paths that continue in the flow direction of the refrigerant,
The evaporator with a cold storage function, wherein the second part is a path in the most upstream flow direction of the refrigerant. In the evaporator with a cool storage function according to claim 1,
It has a tube that extends in the vertical direction and through which refrigerant flows,
The evaporator with a cold storage function, wherein the second portion is a lower portion of the tube. In the evaporator with a cool storage function according to claim 1,
A plurality of paths connected in the flow direction of the refrigerant;
It has a tube that extends in the vertical direction and through which refrigerant flows,
The evaporator with a cool storage function, wherein the second part is a path on the most upstream side in the flow direction of the refrigerant and a lower part of the tube. In the evaporator with a cool storage function according to any one of claims 1 to 4,
The evaporator with a cool storage function is characterized in that the cool storage section is separate from the main body portion of the evaporator and is attached to the main body portion. In the evaporator with a cool storage function according to any one of claims 1 to 4,
The evaporator with a cold storage function, wherein the cold storage unit is incorporated in a main body portion of the evaporator.

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