JP2009041811A - Refrigerating device of container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely prevent breakage of an inner casing in a refrigerating device of a container for cooling the inside of the container. <P>SOLUTION: The inner casing 13 is disposed at an inner side of an outer casing 12 mounted on an opening end face of the container C. At least a part of the inner casing 13 is composed of a resin material having Young's modulus smaller than that of a glass-fiber reinforced plastic. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a container refrigeration apparatus that cools the inside of a container, and particularly relates to a measure for preventing damage to an internal casing.

  Conventionally, container refrigeration apparatuses have been used to cool the inside of containers used for marine transportation and the like.

  Patent Document 1 discloses this type of container refrigeration apparatus. This container refrigeration apparatus is provided at an opening of a container having one end opened. The container refrigeration apparatus has a casing that closes the open end of the container. A storage space outside the container facing the outside of the container is formed in the lower part of the casing. A compressor, a condenser, an outside fan, and the like are housed in the outside storage space.

  On the other hand, in the upper part of the casing, an internal storage space that faces the interior of the container is formed. The internal storage space is a space partitioned by a partition plate with respect to the internal space of the container. The partition plate is supported by side stays provided at both end portions on the inner side of the casing. Moreover, in the said storage space, the internal fan and the evaporator are arrange | positioned and the ventilation path of the internal air is formed.

  During operation of the container refrigeration apparatus, the air in the container is guided to the ventilation path in the storage space by the internal fan and is cooled when passing through the evaporator. The cooled air flows out of the ventilation path and is sent again into the container. As described above, in the container refrigeration apparatus, the inside of the container is refrigerated or frozen by circulating the air while cooling it in the air passage.

In addition, the said casing is comprised by the outer casing which closes the opening end surface of a container, and the inner casing provided in the opening part of a container so that the warehouse inner side of an outer casing may be covered. The outside casing is made of a metal such as an aluminum alloy, and the inside casing is made of FRP (glass fiber reinforced plastic).
JP 2007-93122 A

  By the way, generally, since a force that causes shear deformation acts on the container due to the inclination of the ship, as a product test that simulates the state, an excessive force is applied to the corner of the container. A test (hereinafter referred to as a racking test) is performed to cause shear deformation in the container and confirm the strength of the container at that time. In this racking test, a force is generally applied from one side in the width direction of the container to the upper end corner of the container. Therefore, in the racking test, a force that is larger than the force that normally acts on the above-described outer casing located at the opening of the container is applied. Therefore, in the racking test, a force in the container width direction is applied to the upper portion of the outer casing, and therefore, the upper portion of the outer casing is deformed to wave in the plane orthogonal direction. As a result, stress may concentrate locally in the internal casing formed inside the external casing as the external casing is deformed.

  Here, as described above, the conventional interior casing is made of FRP, and has Young's modulus (elastic coefficient) having a relatively large physical property. Therefore, in the stress concentration part of the inside casing as described above, the generated stress accompanying the predetermined deformation in the elastic region becomes relatively large. As a result, there is a possibility that the stress concentration part of the internal casing may be damaged.

  This invention is made | formed in view of such a point, The objective is to make it avoid the damage of the casing in a container reliably in the refrigeration apparatus for containers which cools the inside of a container.

  The first invention includes an external casing (12) attached to the opening of the container (C) so as to close an open end surface of the box-shaped container (C) whose one end is open, and the external casing (12 And a container refrigeration apparatus for cooling the inside of the container (C). The container refrigeration apparatus has a casing casing (13) provided at the opening of the container (C) so as to cover the inside of the container (C). The container refrigeration apparatus is characterized in that at least a part of the internal casing (13) is made of a resin material having a Young's modulus smaller than that of the glass fiber reinforced plastic.

  In the first invention, at least a part of the inner casing (13) covering the inner side of the outer casing (12) is made of a resin material. This resin material has a Young's modulus smaller than that of glass fiber reinforced plastic (hereinafter abbreviated as FRP). Here, when a force (hereinafter referred to as a racking load) is simultaneously applied to two corners on the same side of the container (C), the outer casing (12) undulates in the direction perpendicular to the plane as described above. However, since the Young's modulus of the inner casing (13) of the present invention is relatively small, the inner casing (13) is elastically deformed so as to follow the outer casing (12). That is, in the internal casing (13) of the present invention, even if the stress is locally concentrated with the deformation of the external casing (12), the generated stress at the stress concentration portion is reduced. As a result, destruction / breakage of the stress concentration site in the internal casing (13) is avoided.

  According to a second aspect of the present invention, in the container refrigeration apparatus of the first aspect, the inner casing (13) includes a first member (13a) made of the resin material, and a Young's modulus greater than the first member (13a). And a second member (38, 39) made of a large material.

  In the second invention, the internal casing (13) includes the first member (13a) and the second member (38, 39). The first member (13a) is made of a resin material having a Young's modulus smaller than that of FRP. Therefore, even if stress concentrates with this 1st member (13a) with a deformation | transformation of an outer casing (12), generated stress is suppressed and it becomes difficult to break. On the other hand, the second member (38, 39) is made of a material having a Young's modulus larger than that of the first member (13a). That is, the second member (38, 39) is less likely to be elastically deformed than the first member (13a). Therefore, by applying the second member (38, 39) to, for example, a heavy load supporting portion, the internal casing (13) can be prevented from being deformed at this portion. Moreover, it can prevent that the airtightness of this site | part falls by an own deformation | transformation by applying this 2nd member (38, 39) to the site | part which requires airtightness.

  According to a third aspect, in the container refrigeration apparatus according to the second aspect, the second member constitutes a support portion (39) on which a predetermined component is supported.

  In the third invention, the second member having a relatively large Young's modulus is provided with a support portion (39) on which predetermined components (for example, a heat exchanger, a fan, a refrigerant pipe, a sensor, etc.) of the container refrigeration apparatus are supported. Constitute. Therefore, it can prevent that a support part (39) deform | transforms with the stress resulting from the load of a component.

  A fourth invention is the container refrigeration apparatus according to any one of the first to third inventions, wherein the resin material constituting at least a part of the inner casing (13) is polypropylene, polyethylene, polycarbonate, acrylonitrile. -It is comprised by any one of butadiene-styrene resin.

  In the fourth invention, at least a part of the internal casing (13) is made of any resin material selected from polypropylene (PP), polyethylene (PE), polycarbonate (PC), and acrylonitrile-butadiene-styrene resin (ABS resin). Composed. These resin materials have a significantly lower Young's modulus than FRP. Therefore, even if the stress concentrates on the portion of the resin material as the outer casing (12) is deformed, the generated stress at the portion can be suppressed. Moreover, since these resin materials have a certain degree of tensile strength, it is possible to prevent the generated stress from exceeding the tensile strength, and it is possible to more reliably avoid the damage of the internal casing (13).

  According to the present invention, since at least a part of the outer casing (12) is made of a resin material having a Young's modulus smaller than FRP, even if the outer casing (12) is deformed by a racking load or the like, The internal casing (13) can be elastically deformed following the deformation. Therefore, the generated stress in the stress concentration portion of the internal casing (13) can be suppressed, and the internal casing (13) can be reliably prevented from being broken.

  In the second invention, the internal casing (13) includes a first member (13a) having a Young's modulus smaller than that of the FRP, and a second member (38, 39) having a Young's modulus greater than that of the first member (13a). It consists of and. Thus, according to the present invention, the first member (13a) is applied to the stress concentration part to avoid the breakage, and the second member (38, 39) is applied to the other part. Elastic deformation can be suppressed.

  In particular, according to the third invention, since the predetermined component is supported by the second member (39), this portion can be prevented from being deformed by the load of the component, and the component can be reliably secured. Can be supported.

  Furthermore, according to the fourth invention, since at least a part of the internal casing (13) is made of any one of the resin materials of PP, PE, PC, and ABS resin, its Young's modulus is effectively reduced. It can be made small and a certain level of tensile strength can be secured. Therefore, the generated stress of the inner casing (13) can be reduced, and the generated stress can be reliably prevented from exceeding the tensile strength. As a result, it is possible to more reliably prevent the inner casing (13) from being damaged along with the deformation of the outer casing (12).

  Moreover, since these resin materials are easy to recycle compared with the conventional FRP, an environment-friendly container refrigeration apparatus can be provided. Furthermore, since these resin materials have a smaller specific gravity than FRP, it is possible to reduce the weight of the container refrigeration apparatus.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  The container refrigeration apparatus (10) according to this embodiment performs refrigeration or freezing in a container (C) used for marine transportation and the like. The container refrigeration apparatus (10) is disposed so as to close the open end of a box-shaped container (C) whose one end on its side is open. More specifically, the casing (11) of the container refrigeration apparatus (10) is fastened and fixed to the opening end of the container (C) by a plurality of bolts.

  The container refrigeration apparatus (10) includes a refrigerant circuit (not shown). That is, the container refrigeration apparatus (10) is configured to cool the air in the container (C) using the refrigeration cycle of the refrigerant circuit. Below, the whole structure of the said container refrigeration apparatus (10) is demonstrated.

<Overall configuration of container refrigeration equipment>
As shown in FIGS. 1 and 2, the container refrigeration apparatus (10) includes a casing having a peripheral edge attached to the container (C) so as to close the open end surface of the container (C) formed in a bottomed cylindrical shape. (11) is provided. The lower part of the casing (11) is formed so as to bulge out toward the inner side of the container (C), thereby forming a recess (11a) outside the lower part of the casing (11). Is done. That is, an outside storage space (S1) is formed on the outer side of the lower part of the casing (11), and an inner storage space (S2) is formed on the inner side of the upper part of the casing (11).

  A partition plate (50) supported by the side stay (40) is disposed inside the casing (11). The partition plate (50) divides the interior of the container (C) from the interior storage space (S2). In addition, the said partition plate (50) is arrange | positioned so that a clearance gap may be provided up and down with respect to the inner surface of a container (C) (refer FIG. 2).

  In the external storage space (S1), a compressor (21), a condenser (23), an external fan (24), a motor (45) of the external fan (24), and the like are provided. The compressor (21) and the condenser (23) are connected to the refrigerant circuit (not shown). The outside fan (24) is rotated by a motor (45) to attract outside air into the outside storage space (S1) and send it to the condenser (23). In the condenser (23), heat is exchanged between the outside air and the refrigerant. That is, the outside storage space (S1) constitutes an outside ventilation path.

  In the internal storage space (S2), an evaporator (25), an internal fan (26), and a motor (46) for the internal fan (26) are provided in the upper part inside the internal casing of the casing (11). Yes. Similarly to the condenser (23), the evaporator (25) is also connected to a refrigerant circuit (not shown). The internal fan (26) is rotated by a motor (46), attracts air in the container (C) from the gap above the partition plate (50), and sends it to the evaporator (25). is there. Then, the internal air that has undergone heat exchange with the refrigerant in the evaporator (25) is returned to the internal side from the lower gap of the partition plate (50) by the internal fan (26). It is. That is, the said storage space (S2) comprises the inner side ventilation path.

  As shown in FIG. 5, an evaporator holding frame (15) for holding the internal fan (26), the motor (46), and the evaporator (25) is provided in the upper part of the casing (11) inside the casing. It is provided over the width direction. The evaporator holding frame (15) is placed above the evaporator (25) so that the internal fan (26) causes the internal air to flow downward from above with respect to the evaporator (25). The inner fan (26) and the motor (46) are configured to be held.

  The evaporator holding frame (15) has one surface of the enlarged plate portion (42, 42) constituting the upper portion of the side stay (40, 40) connected to both ends in the width direction. As will be described in detail later, in the present embodiment, mounting brackets (16, 16) are provided on the casing (11) corresponding to the connecting portions of the enlarged plate portions (42, 42).

  Further, the central portion in the width direction of the evaporator holding frame (15) is connected to the upper end portion of the frame support member (43) that is fixed to the central portion in the width direction on the inner side of the casing (11) and extends vertically. ing.

  The side stay (40) is fixed to the inner side of the casing (11). Specifically, the side stay (40) includes a column portion (41) connected to a lower portion of the casing (11) bulging inside the warehouse, and the column portion in a state of being placed on the column portion (41). (41) and the enlarged plate part (42) connected to the upper part of the casing (11).

  Thus, the evaporator holding frame (15) is supported at both ends in the width direction by the side stay (40) and at the center in the width direction by the frame support member (43). The frame support member (43) is a columnar member having a substantially U-shaped cross section, and is provided to extend in the vertical direction at the central portion in the width direction inside the warehouse at the bottom of the casing (11). Yes.

  As shown in FIG. 1, the casing (11) is provided with a viewing window (27) and a ventilator (28) provided with a door that can be opened and closed at the time of maintenance. This ventilator (28) constitutes a ventilation device for ventilating the inside of the cabinet. An electrical component box (29) is disposed in a position adjacent to the external fan (24) in the external storage space (S1) of the casing (11).

  As shown in FIG. 2, the casing (11) includes an outer casing (12) located on the outer side and an inner casing (13) located on the inner side.

  The said exterior casing (12) is comprised with metal aluminum alloys, and is attached to the opening part of this container (C) so that the opening end surface of a container (C) may be plugged up. As shown in FIG.2 and FIG.3, the outer casing (12) is formed so that the lower part bulges to the inner side. The outer casing (12) includes an upper part (32) formed in a substantially planar shape, a lower bulging part (33) swelled in a substantially rectangular parallelepiped shape inside the warehouse, and an outer casing ( 12) and a mounting portion (31) having a rectangular shape in front view, which is located at the outer peripheral end portion. A flange having a substantially P-shaped cross section (not shown) is welded to a portion extending in the vertical direction of the mounting portion (31) (both ends in the width direction of the outer casing) and a plurality of bolt holes are provided. It has been. In addition, flanges having a substantially F-shaped cross section made of an aluminum alloy (not shown) are provided at portions extending in the lateral direction of the mounting portion (31) (both ends in the vertical direction of the external casing).

  As shown in FIG. 3, the upper part (32) of the outer casing (12) is formed so as to be continuous with the upper side of the lower bulge part (33). Two openings (32a, 32a) are formed. Specifically, these openings (32a, 32a) are formed in a substantially rectangular shape, and are formed side by side in the upper direction (32).

  The lower bulging portion (33) is composed of an upper surface portion (33a), two side surface portions (33b, 33c), a lower surface portion (33d), and a bottom surface portion (33e). Specifically, the upper surface portion (33a), the lower surface portion (33d), and the bottom surface portion (33e) are each formed in a substantially rectangular shape, while the side surface portions (33b, 33c) are one leg portion. Is formed in a substantially trapezoidal shape. Thereby, the said lower side bulging part (33) is formed in the box shape in which an upper surface part (33a) is extended diagonally downward toward the inside of a store | warehouse | chamber. A through-hole (33f) for inserting the refrigerant pipe is opened in the bottom surface portion (33e). Specifically, a suction pipe connecting the compressor (21) on the outside of the warehouse and the evaporator (25) on the inside of the warehouse is inserted through the through hole (33f).

  The internal casing (13) includes an internal casing body (13a), two window frames (38) and a pipe support (39) that are detachably attached to the internal casing body (13a). ing. As shown in FIGS. 2 and 4, the inner casing body (13 a) is formed along the outer casing (12) and swells toward the inner side corresponding to the outer casing (12). The lower cover part (37) to take out and the flat upper cover part (36) are provided. The lower covering portion (37) and the upper covering portion (36) are integrally formed, and the upper covering portion (36) is provided so as to be continuous with the upper side of the lower covering portion (37). Yes.

  The upper covering portion (36) includes a covering portion main body (36a), an upper frame portion (36b) and a lateral frame portion (36c, provided in a substantially U-shape so as to surround the covering portion main body (36a). 36d). These upper frame part (36b) and horizontal frame part (36c, 36d) are located on the upper side and the side of the covering part main body (36a), respectively, and the horizontal frame extends from both ends of the upper frame part (36b). The parts (36c, 36d) are formed in a substantially U shape as a whole by extending downward. Further, the upper frame part (36b) and the horizontal frame parts (36c, 36d) slightly protrude toward the inner side with respect to the covering part main body (36a). The cover body (36a) has two viewing window openings (36e, 36e) corresponding to the openings (32a) of the upper part (32) of the outer casing (12). ing.

  The lower covering portion (37) has substantially the same shape as the lower bulging portion (33) of the outer casing (12), and has an upper surface portion (37a), two side surface portions (37b, 37c), and a lower surface portion. (37d) and a bottom surface portion (37e). The lower covering portion (37) is slightly larger than the lower bulging portion (33) so that the lower bulging portion (33) of the outer casing (12) can be covered from the inner side. Is formed. The bottom surface (37e) of the lower bulge (33) has a through hole for inserting the refrigerant pipe so as to correspond to the through hole (33f) of the bottom surface (33e) of the outer casing (12). The mouth (37f) is open.

  The lower surface (37d) has an inlet for injecting the foaming agent (60) into the space (V) (foaming space) between the outer casing (12) and the inner casing (13). (Not shown) is formed.

  Moreover, as shown in the said FIG.2 and FIG.4, the outer peripheral edge part is bend | folded by the said housing | casing casing (13) on the outer side (outside casing side), and it combines with the said outer casing (12). In this state, the outer peripheral end of the inner casing (13) is positioned on the attachment portion (31) of the outer casing (12).

  Thus, when the inner casing (13) is attached to the outer casing (12), the foaming space (V) for forming a heat insulating layer between the outer casing (12) and the inner casing (13). So that the upper covering portion (36) covers the inner side of the upper portion (32), and the lower covering portion (37) covers the inner side of the lower bulging portion (33). . Then, the foaming space (V) is injected with a foaming agent (60) from the inlet of the internal casing (13) to foam the foaming agent (60), as shown in FIG. A heat insulating layer (14) is formed.

  Furthermore, in this embodiment, as shown in FIG.4 and FIG.5, the said vaporization is carried out on the warehouse outer side of the horizontal frame part (36c, 36c) which comprises the upper side coating | coated part (36) of the said inner casing (13). Mounting brackets (16) are provided corresponding to the attachment parts (bolt fastening parts (42a, 42a)) of the enlarged plate part (42) of the side stay (40) that supports both ends of the holder holding frame (15) ing. The mounting bracket (16) is a metal plate member formed in a substantially rectangular shape, and includes a plurality of bolt fastening portions (42a, 42a) (in the drawing) in the enlarged plate portion (42) of the side stay (40). In the example, it is arranged so as to straddle two places).

  The two window frames (38) are provided at positions corresponding to the openings (36e) in the upper part (32) of the internal casing body (13a). Each window frame (38) is formed in a substantially rectangular cylindrical shape, and a transparent plate made of resin or glass is fitted and fixed therein. The interior of the window frame (38) is partitioned forward and backward in the axial direction by this transparent plate. Each window frame (38) is formed separately from the internal casing body (13a), and is configured to be detachable from the upper part (32) of the internal casing body (13a).

  Specifically, for example, each window frame (38) has a claw portion projecting toward the inner casing body (13a) side, while the upper portion (32) of the inner casing body (13a) An engaging groove that can be engaged with the portion is formed. Each window frame (38) can be attached to the internal casing body (13a) by locking its claw portion in the engaging groove. The window frame (38) is attached to the internal casing body (13a) in a state of passing through the openings (32a, 36e) of the external casing (12) and the internal casing body (13a). In addition, a foaming agent (60) is inject | poured into the foaming space (V) mentioned above, after attaching each window frame (38). At this time, since the inside of the window frame (38) is partitioned from the foaming space (V), the foaming agent (60) does not enter the inside of the window frame (38).

  The said pipe | tube support part (39) is provided in the position corresponding to the through-hole (37f) of the bottom face part (37e) of a lower side bulging part (33). The pipe support (39) is formed in a cylindrical shape into which the refrigerant pipe can be inserted. That is, the pipe support part (39) constitutes a support part for supporting the refrigerant pipe as a component of the container refrigeration apparatus. The pipe support (39) is attached to the internal casing body (13a) in a state of passing through the through-holes (33f) of the external casing (12) and the internal casing body (13a). As with the window frame (38) described above, the foaming agent (60) is injected into the foaming space (V) after the pipe support (39) is attached. At this time, since the inside of the pipe support part (39) is partitioned from the foaming space (V), the foaming agent (60) does not enter the inside of the pipe support part (39).

<Material and manufacturing method of casing inside>
Next, the material and manufacturing method of the internal casing (13) will be described in detail. In the internal casing (13), the internal casing body (13a) is made of polypropylene (PP). That is, the internal casing body (13a) is a resin material having a Young's modulus smaller than that of the FRP, and constitutes the first member of the present invention. In addition, the inner casing body (13a) preferably has a lower Young's modulus than the outer casing (12).

  The inside casing body (13a) is manufactured by hot press molding. Specifically, first, a plate-shaped PP resin of about 2 m × 2 m is heated with a heater or the like for about 2 minutes, and then this PP resin is pressed between predetermined dies (upper mold and lower mold) for about 1 minute. Thus, the inside casing body (13a) can be obtained.

  Conventional FRP casings have SMC (Sheet Molding Compound) molding in which a sheet of resin and glass fiber is placed in a mold and heated and pressurized, so a relatively long molding time (for example, 35 minutes) is required. However, in the manufacturing method of the present embodiment, the in-compartment casing body (13a) can be formed in an extremely shorter time (for example, 3 minutes). That is, in the hot press molding, the inner casing body (13a), which is a large molded product, can be molded easily and in a short time.

  Further, in the internal casing (13), the window frame (38) and the pipe support portion (39) which are separate from the internal casing body (13a) are made of a resin material (for example, polypropylene) containing glass fiber. Yes. That is, the window frame (38) and the pipe support part (39) are made of a material having a Young's modulus larger than that of the internal casing body (13a) and constitute the second member of the present invention.

  A window frame (38) and a piping support part (39) are obtained by carrying out injection molding (injection molding) of the polypropylene raw material containing 3% of glass fiber. When the window frame (38) and the pipe support (39) are formed by injection molding in this way, the processing accuracy is improved as compared with, for example, hot press molding. Therefore, the window frame (38) and the pipe support (39) are required to have sufficient sealing performance around them. However, by improving the processing accuracy by injection molding these, it is necessary to ensure sufficient sealing performance. Can do.

-Driving action-
Operation of the container refrigeration apparatus (10) is started by starting the compressor (21), the external fan (24), and the internal fan (26). In the refrigerant circuit of the container refrigeration apparatus (10), the refrigerant discharged from the compressor (21) is sent to the condenser (23). In the condenser (23), the refrigerant circulating inside exchanges heat with outside air sent by the outside fan (24). As a result, the refrigerant dissipates heat to the outside air and condenses.

  The refrigerant condensed in the condenser (23) is depressurized by the expansion valve and then sent to the evaporator (25). In the evaporator (25), the refrigerant circulating in the interior exchanges heat with the internal air sent by the internal fan (26). As a result, the refrigerant absorbs heat from the internal air and evaporates, and the internal air is cooled. As shown in FIG. 2, the internal air flows into the external storage space (S1) from above the partition plate (50) and passes through the evaporator (25). And after cooling with an evaporator (25), it returns to the inside from the lower side of a partition plate (50). The refrigerant evaporated in the evaporator (25) is sucked into the compressor (21) and compressed again.

<Evaluation of stress generated in the casing in the cabinet>
By the way, when the force (racking load) in the direction indicated by the white arrow in FIG. 5 is applied to the container (C), the upper portion of the outer casing (12) is deformed to wave in the direction perpendicular to the plane. There is. With such deformation of the outer casing (12), the inner casing (13) covering the back side of the outer casing (12) is subjected to stress in the longitudinal direction of the container (C), and locally Stress may concentrate. As a result, in the conventional internal casing, there is a possibility that the stress concentration portion is damaged.

  In contrast, in the internal casing (13) of the present embodiment, the internal casing body (13a) is made of polypropylene. Polypropylene has a significantly smaller Young's modulus than conventional FRP, so when the outer casing (12) is deformed by the racking load as described above, the inner casing body (13a) is deformed in this way. Elastically deforms so as to follow. Therefore, in the internal casing body (13a), the generated stress at the stress concentration site can be suppressed, so that the internal casing body (13a) can be prevented from being broken or damaged.

The evaluation result of the stress generated in the internal casing (13) will be described with reference to FIGS. In this evaluation, as FRP to be compared, an unsaturated polyester containing about 27% by weight of glass fiber (Young's modulus = 1100 kgf / mm ² , tensile strength = 8 kg / mm ² ) was used. When the inner casing is formed of FRP as in the conventional example, a stress of 7.8 kg / mm ² is generated in the stress concentration portion described above, and the elongation amount (strain amount) is 7.1 μm. . On the other hand, when the internal casing body (13a) is formed of polypropylene (PP) as in this embodiment, the stress generated for the elongation equivalent to FRP (7.1 μm) is 0.9 kg / mm ^2. Thus, the generated stress at the stress concentration site can be extremely reduced (see FIG. 7).

  In addition, when the internal casing is formed of FRP as in the conventional example, the ratio of the generated stress (equivalent to an elongation of 7.1 μm) to the tensile strength (hereinafter referred to as margin) is 97.5%. On the other hand, in the case main body (13a) made of PP, the margin rate when compared with the same amount of elongation is significantly reduced to 26.4%. Therefore, in the internal casing (13) of this embodiment, it is possible to reliably prevent the generated stress at the stress concentration portion from reaching the tensile strength.

-Effect of the embodiment-
In the above embodiment, the internal casing body (13a) is made of PP. As described above, PP has a smaller Young's modulus than FRP, and further has a small margin. For this reason, even if the outer casing (12) is deformed by a racking load or the like, the inner casing (13) can be elastically deformed following the deformation, and the inner casing (13) can be reliably damaged. Can be avoided.

  Moreover, in the said embodiment, the window frame (38) and piping support part (39) of the inside casing (13) are comprised with the resin material (polypropylene) containing glass fiber. That is, the window frame (38) and the pipe support part (39) are made of a resin material having a larger Young's modulus than the internal casing body (13a). Therefore, it can prevent that a window frame (38) and a piping support part (39) receive a predetermined stress, and are elastically deformed. As a result, it is possible to prevent the sealing performance around the window frame (38) and the pipe support (39) from being impaired due to such elastic deformation.

  In addition, since the refrigerant pipe is supported by the pipe support portion (39), stress is easily applied to this portion. However, since the pipe support portion (39) has a relatively large Young's modulus, the pipe support portion (39) is not significantly deformed and can support the refrigerant pipe satisfactorily.

  Furthermore, in the said embodiment, since the internal casing main body (13a) is formed by hot press molding, the internal casing (13) can be manufactured easily and in a short time. On the other hand, since the window frame (38) and the pipe support part (39) are formed by injection molding, the processing accuracy of the window frame (38) and the pipe support part (39) is improved, and the surrounding seals are improved. Enough.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  In the said embodiment, although the internal casing main body (13a) is comprised with the polypropylene, another material may be sufficient if it is a resin material whose Young's modulus is smaller than FRP. In particular, this resin material has a ratio of the generated stress (tensile stress) with a predetermined elongation amount to the tensile strength (that is, the above margin) is smaller than FRP when compared with the same elongation amount. Is preferred. Specifically, polyethylene (PE), polycarbonate (PC), and acrylonitrile-butadiene-styrene resin (ABS resin) are suitable as the resin material constituting at least a part of the internal casing (13). As shown in FIGS. 6 and 7, these resin materials can also reduce the generated stress as compared with FRP, and the margin ratio is remarkably reduced. In particular, since PE has a very small margin rate, it is possible to more reliably avoid damage to the inner casing (13) due to deformation of the outer casing (12).

  Moreover, in the said embodiment, although the window frame (38) and the piping support part (39) are comprised with another material (2nd member) with a larger Young's modulus than the internal casing main body (13a), (38) and the pipe support part (39) may be integrated with the internal casing body (13a), and the entire internal casing (13) may be made of polypropylene.

  Furthermore, in the said embodiment, you may make it comprise site | parts other than a window frame (38) and a piping support part (39) with a 2nd member. Specifically, in the internal casing (13), for example, the second part is used to support the above-described evaporator (25), evaporator holding frame (15), internal fan (26), motor (46), and the like. You may make it comprise with a member. Thereby, it can suppress that the support part of these component parts (25,15,26,46) elastically deforms, and each component part (25,15,26,46) is reliably carried out by the inside casing (13). Can be supported.

  Further, in the internal casing (13), a metal reinforcing plate (sheet metal) may be laid on the support portion of such component parts (25, 15, 26). In this case, for example, a sheet metal is riveted to the back side of the support portion of the internal casing (13). Thereby, such a deformation | transformation of a support part can be prevented more reliably, and a component (25,15,26) can be supported favorably.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention relates to a container refrigeration apparatus that cools the inside of a container, and is particularly useful as a countermeasure for preventing damage to an internal casing.

FIG. 1 is a perspective view of the container refrigeration apparatus according to the present embodiment as viewed from the outside of the warehouse. 2 is a cross-sectional view taken along line II-II in FIG. FIG. 3 is a perspective view of the outer casing as viewed from the inner side. FIG. 4 is a perspective view of a casing formed by covering the inner side of the outer casing with the inner casing as viewed from the inner side. FIG. 5 is a perspective view of the casing with the evaporator holding frame attached to the inner side, as viewed from the inner side. FIG. 6 is a table comparing the physical property data for each material of the internal casing. FIG. 7 is a graph showing the relationship between Young's modulus and generated stress for each material of the internal casing.

Explanation of symbols

C container
10 Container refrigeration equipment
11 Casing
12 Outer casing
13 Inside casing
13a Inside casing body (first member)
38 Window frame (second member)
39 Piping support (second member, support)

Claims (4)

The external casing (12) attached to the opening of the container (C) so as to close the opening end surface of the box-shaped container (C) whose one end is open, and the internal side of the external casing (12) are covered And a container refrigeration apparatus for cooling the inside of the container (C), having an in-chamber casing (13) provided at the opening of the container (C),
At least a part of the internal casing (13) is made of a resin material having a Young's modulus smaller than that of glass fiber reinforced plastic. In claim 1,
The inner casing (13) includes a first member (13a) made of the resin material and a second member (38, 39) made of a material having a Young's modulus larger than that of the first member (13a). A container refrigeration apparatus characterized by comprising: In claim 2,
The said 2nd member comprises the support part (39) by which a predetermined component is supported, The container refrigeration apparatus characterized by the above-mentioned. In any one of Claims 1 thru | or 3,
The container refrigeration apparatus wherein the resin material constituting at least a part of the inner casing (13) is made of any one of polypropylene, polyethylene, polycarbonate, acrylonitrile-butadiene-styrene resin .

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