JP2021139802A - Transport refrigerator and transport container - Google Patents

Abstract

To suppress transfer of heat from the outside to an interior space.SOLUTION: A first passage member (80) puts the outside and interior space (20) into communication and guides a temperature sensor (50) into the interior space (20). A second passage member (60) is disposed on an internal space (20) side of the first passage member (80), and places the temperature sensor (50) in the interior space (20). The first passage member (80) and the second passage member (60) consist of separate members.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to transport refrigeration equipment and transport containers.

Patent Document 1 discloses a configuration in which a cylinder is provided between a wall outside the refrigerator and a wall inside the refrigerator, and a temperature sensor is arranged inside the cylinder to measure the temperature of the space inside the refrigerator. ..

U.S. Pat. No. 6089110

By the way, in the invention of Patent Document 1, a cylinder for arranging the temperature sensor is integrally formed from the outside of the refrigerator to the space inside the refrigerator. Therefore, there is a problem that the heat outside the refrigerator is conducted to the temperature sensor via the cylinder.

An object of the present disclosure is to suppress the conduction of heat outside the refrigerator to the temperature sensor.

The first aspect of the present disclosure is a transport refrigerating device provided with a casing (11) to be attached to the open end of the container body (2), and a temperature sensor (50) for detecting the temperature of the internal space (20). ) And the first passage member (80) provided in the casing (11), communicating the outside and the inside space (20), and guiding the temperature sensor (50) to the inside space (20). And a second passage member (60) arranged on the internal space (20) side of the first passage member (80) and arranging the temperature sensor (50) in the internal space (20). The first passage member (80) and the second passage member (60) are made of separate members.

In the first aspect, the first passage member (80) communicates the outside and the inside space (20) to guide the temperature sensor (50) to the inside space (20). The second passage member (60) is arranged on the internal space (20) side of the first passage member (80), and the temperature sensor (50) is arranged in the internal space (20). The first passage member (80) and the second passage member (60) are composed of separate members. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

In the second aspect of the present disclosure, in the first aspect, the first passage member (80) and the second passage member (60) are arranged apart from each other.

In the second aspect, the first passage member (80) and the second passage member (60) are arranged apart from each other. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

A third aspect of the present disclosure is, in the first or second aspect, the casing (11) has an outer wall (13) facing the outside and an inner wall (14) facing the inner space (20). The first passage member (80) is fixed to the outer wall (13), and the second passage member (60) is fixed to the inner wall (14).

In the third aspect, the first passage member (80) is fixed to the outer wall (13) of the refrigerator. The second passage member (60) is fixed to the inner wall (14) of the refrigerator. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

In the fourth aspect of the present disclosure, in the third aspect, a hole (13a) is formed in the outer wall (13) of the refrigerator, and the first passage member (80) is inserted into the hole (13a). A first position having a passage body (81) and a protrusion (84) provided on the outer peripheral surface of the passage body (81), through which the protrusion (84) can pass through the hole (13a). And the second position where the protrusion (84) engages with the surface of the outer wall (13) on the inner space (20) side.

In the fourth aspect, the first passage member (80) has a passage body (81) and a protrusion (84). The first passage member (80) is configured to be changeable to a first position and a second position. The first position is a position where the protrusion (84) can pass through the hole (13a) of the outer wall (13) of the refrigerator. The second position is the position where the protrusion (84) engages with the surface of the outer wall (13) on the inner space (20) side.

Thereby, the work of assembling the first passage member (80) to the outer wall (13) of the refrigerator can be easily performed.

In a fifth aspect of the present disclosure, in the fourth aspect, the first passage member (80) can be changed to the first position and the second position by rotating the passage body (81). It is configured in.

In the fifth aspect, the first position and the second position of the first passage member (80) can be changed by the rotation of the passage body (81).

Thereby, by rotating the first passage member (80), the work of assembling the first passage member (80) to the outer wall (13) of the refrigerator can be easily performed.

A sixth aspect of the present disclosure is that in any one of the first to fifth aspects, the temperature sensor (50) includes a detection unit (51) that detects the temperature of the internal space (20). The second passage member (60) has a lead wire (52) connected to the detection unit (51), and the second passage member (60) has a curved portion (72) formed in a curved shape in a plan view.

In the sixth aspect, the temperature sensor (50) has a detector (51) and a lead wire (52). The second passage member (60) has a curved portion (72). The curved portion (72) is formed in a curved shape in a plan view.

As a result, the temperature sensor (50) can be arranged at a specific location in the interior space (20) while ensuring a distance that can suppress the conduction of heat outside the refrigerator.

A seventh aspect of the present disclosure is a transportation container provided with the transportation refrigerating apparatus (10) and the container body (2) according to any one of the first to sixth aspects.

In the seventh aspect, the transport refrigerating apparatus (10) according to any one of the first to sixth aspects is attached to the container body (2). As a result, in the shipping container, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

FIG. 1 is a perspective view of the transportation container according to the embodiment as viewed from the front side. FIG. 2 is a side sectional view schematically showing the internal structure of the shipping container. FIG. 3 is a piping system diagram of the refrigerant circuit of the refrigerating apparatus for transportation. FIG. 4 is a plan sectional view showing the configurations of the temperature sensor, the first passage member, and the second passage member. FIG. 5 is a side sectional view showing the configurations of the temperature sensor, the first passage member, and the second passage member. FIG. 6 is a perspective view showing the configurations of the temperature sensor, the first passage member, and the second passage member. FIG. 7 is a plan view showing a state in which the cover member is opened. FIG. 8 is a plan sectional view showing a state before the first passage member is fixed to the outer wall of the refrigerator. FIG. 9 is a view of the state before fixing the first passage member to the outer wall of the refrigerator from the inside of the refrigerator. FIG. 10 is a plan sectional view showing a state in which the first passage member is fixed to the outer wall of the refrigerator. FIG. 11 is a view of the state in which the first passage member is fixed to the outer wall of the refrigerator as viewed from the inside of the refrigerator. FIG. 12 is a plan sectional view showing a state before the temperature sensor is inserted into the first passage member and the second passage member. FIG. 13 is a plan sectional view showing a state in which the temperature sensor is being inserted into the first passage member and the second passage member. FIG. 14 is a plan sectional view showing a state in which the temperature sensor is positioned by arranging the elastic member inside the first passage member. FIG. 15 is a plan sectional view showing a state in which the temperature sensor is being pulled out from the first passage member and the second passage member.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. It should be noted that the following embodiments are essentially preferred examples and are not intended to limit the scope of the present invention, its applications, or its uses.

<< Embodiment >>
The present disclosure is a shipping container (1). As shown in FIGS. 1 and 2, the transportation container (1) includes a container body (2) and a transportation refrigerating device (10) provided in the container body (2). The shipping container (1) is used for marine transportation. The shipping container (1) is transported by a marine transporter such as a ship.

<Container body>
The container body (2) is formed in a hollow box shape. The container body (2) is formed horizontally. An opening is formed at one end of the container body (2) in the longitudinal direction. The opening of the container body (2) is closed by the transport refrigerating device (10). A storage space (5) for accommodating the goods to be transported is formed in the chamber of the container body (2). The goods to be transported are stored in the storage space (5). The temperature of the air in the containment space (5) (also called the air inside the refrigerator) is adjusted by the transport refrigerating device (10).

<Transport refrigeration equipment>
The transport refrigeration system (10) is attached to the opening of the container body (2). The transport refrigerator (10) includes a casing (11) and a refrigerant circuit (C).

<casing>
As schematically shown in FIG. 2, the casing (11) includes a partition wall (12) and a partition plate (15). An internal flow path (20) is formed inside the partition wall (12). The internal flow path (20) corresponds to the internal space. Air for cooling the goods to be transported in the storage space (5) flows through the internal flow path (20). An outer chamber (S) is formed on the outside of the partition wall (12). The internal flow path (20) and the external chamber (S) are separated by a partition wall (12).

The partition wall (12) includes an outer wall (13) and an inner wall (14). The outer wall (13) of the refrigerator is located outside the container body (2). The outer wall (13) faces the outside of the refrigerator. The inner wall (14) of the refrigerator is located inside the container body (2). The inner wall (14) faces the inner flow path (20). The outer wall (13) and the inner wall (14) of the refrigerator are made of, for example, an aluminum alloy.

The outer wall (13) of the refrigerator closes the opening of the container body (2). The outer wall (13) of the refrigerator is attached to the peripheral edge of the opening of the container body (2). The lower part of the outer wall (13) bulges toward the inside of the container body (2). An outer chamber (S) is formed in a portion of the outer wall (13) that bulges toward the inside of the container body (2).

The inner wall (14) faces the outer wall (13). The inner wall (14) has a shape along the outer wall (13). The inner wall (14) of the refrigerator is arranged at a distance from the outer wall (13) of the refrigerator. The lower part of the inner wall (14) bulges toward the inside of the container body (2). A heat insulating material (16) is provided between the inner wall (14) and the outer wall (13).

The partition plate (15) is arranged inside the container body (2) rather than the inner wall (14) of the refrigerator. An internal flow path (20) is formed between the partition wall (12) and the partition plate (15). An inflow port (21) is formed between the upper end of the partition plate (15) and the top plate of the container body (2). An outlet (22) is formed between the lower end of the partition plate (15) and the lower end of the partition wall (12). The internal flow path (20) is formed from the inflow port (21) to the outflow port (22).

The internal flow path (20) includes an upper flow path (23) and a lower flow path (24). The upper flow path (23) is located above the internal flow path (20). The lower flow path (24) is located below the internal flow path (20). The lower flow path (24) is located at a position corresponding to the bulging portion of the partition wall (12).

<Element parts of refrigerant circuit>
The refrigerant circuit (C) has a refrigerant filled therein. The refrigerant circuit (C) performs a vapor compression refrigeration cycle by circulating the refrigerant. The refrigerant circuit (C) includes a compressor (31), an external heat exchanger (32), an expansion valve (33), an internal heat exchanger (37), and a refrigerant pipe connecting them.

The compressor (31) is arranged in the first space (S1) corresponding to the lower part of the outdoor chamber (S). The compressor (31) sucks in low-pressure refrigerant and compresses it. The compressor (31) discharges the compressed refrigerant as a high-pressure refrigerant.

The external heat exchanger (32) is arranged in the second space (S2) corresponding to the upper part of the external chamber (S). The external heat exchanger (32) is a fin-and-tube type. The external heat exchanger (32) is a so-called four-sided heat exchanger. The outer shape of the external heat exchanger (32) is substantially square when viewed from the front. In other words, the external heat exchanger (32) has heat exchangers on the upper side, the lower side, the right side, and the left side, respectively, when viewed from the front. The external heat exchanger (32) functions as a condenser or a radiator.

The internal heat exchanger (37) is arranged in the internal flow path (20). The internal heat exchanger (37) is supported between the partition wall (12) and the partition plate (15). The internal heat exchanger (37) is arranged above the bulging portion of the internal wall (14). The internal heat exchanger (37) is a fin-and-tube type. The internal heat exchanger (37) functions as an evaporator.

<Outside fan>
The transport refrigeration system (10) includes one external fan (34). The outside fan (34) is arranged in the second space (S2) of the outside room (S). The external fan (34) is arranged inside the four heat exchange portions of the external heat exchanger (32). The outside fan (34) is a propeller fan.

When the outside fan (34) is operated, the outside air flows from the outside to the inside of the outside heat exchanger (32). The air inside the external heat exchanger (32) is blown out to the outside of the casing (11).

<Fan in the warehouse>
The transport refrigeration system (10) is equipped with two internal fans (35). The internal fan (35) is arranged in the upper flow path (23) of the internal flow path (20). The internal fan (35) is arranged above the internal heat exchanger (37). The internal fan (35) is arranged on the upstream side of the air flow from the internal heat exchanger (37). The internal fan (35) is a propeller fan. The number of internal fans (35) may be one or three or more.

When the internal fan (35) operates, the internal air in the accommodation space (5) flows from the inflow port (21) into the upper flow path (23) of the internal flow path (20). The air in the upper flow path (23) of the internal flow path (20) passes through the internal heat exchanger (37) and the heater (H), and flows through the lower flow path (24). The air in the lower flow path (24) flows out from the outlet (22) to the accommodation space (5).

<heater>
The transport refrigeration system (10) includes a heater (H). The heater (H) is arranged below the internal heat exchanger (37). The heater (H) is attached to the lower part of the internal heat exchanger (37). When the heater (H) operates, the internal heat exchanger (37) is heated. The heat of the heater (H) melts the frost adhering to the internal heat exchanger (37). The heater (H) is used for defrosting the internal heat exchanger (37).

<Electrical equipment box>
As shown in FIG. 1, the transport refrigerating apparatus (10) has an electrical component box (36). The electrical component box (36) is arranged in the second space (S2) of the outdoor chamber (S). A reactor, a power supply circuit board, a control board, and the like are housed inside the electrical component box (36).

<Details of refrigerant circuit>
The details of the refrigerant circuit (C) will be described with reference to FIG. In FIG. 3, the portion surrounded by the broken line indicates the inside of the refrigerator, and the other portion indicates the outside of the refrigerator.

The refrigerant circuit (C) has a compressor (31), an external heat exchanger (32), an expansion valve (33), and an internal heat exchanger (37) as main components. The expansion valve (33) is an electronic expansion valve whose opening degree can be adjusted.

The refrigerant circuit (C) has a discharge pipe (41) and a suction pipe (42). One end of the discharge pipe (41) is connected to the discharge portion of the compressor (31). The other end of the discharge pipe (41) is connected to the gas end of the external heat exchanger (32). One end of the suction pipe (42) is connected to the suction part of the compressor (31). The other end of the suction pipe (42) is connected to the gas end of the internal heat exchanger (37).

The refrigerant circuit (C) includes a liquid pipe (43), a receiver (44), a cooling heat exchanger (45), a first on-off valve (46), a communication pipe (47), a second on-off valve (48), and an injection pipe. It has (49) and an injection valve (49a).

One end of the liquid pipe (43) is connected to the liquid end of the external heat exchanger (32). The other end of the liquid pipe (43) is connected to the liquid end of the internal heat exchanger (37). The receiver (44) is provided in the liquid tube (43). The receiver (44) is a container for storing the refrigerant.

The cooling heat exchanger (45) has a first flow path (45a) and a second flow path (45b). The cooling heat exchanger (45) exchanges heat between the refrigerant in the first flow path (45a) and the refrigerant in the second flow path (45b). The cooling heat exchanger (45) is, for example, a plate type heat exchanger. The first flow path (45a) is a part of the liquid pipe (43). The second flow path (45b) is a part of the injection tube (49). The cooling heat exchanger (45) cools the refrigerant flowing through the liquid pipe (43).

The first on-off valve (46) is provided in a portion of the liquid pipe (43) between the receiver (44) and the first flow path (45a). The first on-off valve (46) is a solenoid valve that can be opened and closed.

The communication pipe (47) communicates the high-pressure line and the low-pressure line of the refrigerant circuit (C). One end of the communication pipe (47) is connected to the discharge pipe (41). The other end of the communication pipe (47) is connected to the portion of the liquid pipe (43) between the expansion valve (33) and the internal heat exchanger (37).

The second on-off valve (48) is provided in the communication pipe (47). The second on-off valve (48) is a solenoid valve that can be opened and closed.

The injection pipe (49) introduces the refrigerant into the medium pressure portion of the compressor (31). One end of the injection tube (49) is connected to a portion of the liquid tube (43) between the receiver (44) and the first flow path (45a). The other end of the injection tube (49) is connected to the medium pressure portion of the compressor (31). The intermediate pressure, which is the pressure of the medium pressure portion, is the pressure between the suction pressure and the discharge pressure of the compressor (31).

The injection valve (49a) is provided in a portion of the injection pipe (49) on the upstream side of the second flow path (45b). The injection valve (49a) is an electronic expansion valve whose opening degree can be adjusted.

<Operating operation of refrigeration equipment for transportation>
The basic operation of the transport refrigeration system (10) will be described. When the transport refrigerating device (10) is operated, the compressor (31), the outside fan (34), and the inside fan (35) are operated. The first on-off valve (46) opens. The second on-off valve (48) closes. The opening degree of the expansion valve (33) is adjusted. The opening degree of the injection valve (49a) is adjusted.

The refrigerant compressed by the compressor (31) flows through the external heat exchanger (32). In the external heat exchanger (32), the refrigerant dissipates heat to the external air and condenses. The condensed refrigerant passes through the receiver (44). A part of the refrigerant that has passed through the receiver (44) flows through the first flow path (45a) of the cooling heat exchanger (45). The rest of the refrigerant that has passed through the receiver (44) flows through the injection pipe (49) and is depressurized to an intermediate pressure at the injection valve (49a). The decompressed refrigerant is introduced into the medium pressure portion of the compressor (31).

In the cooling heat exchanger (45), the refrigerant in the second flow path (45b) absorbs heat from the refrigerant in the first flow path (45a) and evaporates. As a result, the refrigerant in the first flow path (45a) is cooled. In other words, the degree of supercooling of the refrigerant flowing through the first flow path (45a) increases.

The refrigerant cooled by the cooling heat exchanger (45) is depressurized to a low pressure by the expansion valve (33). The decompressed refrigerant flows through the internal heat exchanger (37). In the internal heat exchanger (37), the refrigerant absorbs heat from the internal air and evaporates. As a result, the internal heat exchanger (37) cools the internal air. The evaporated refrigerant is sucked into the compressor (31) and compressed again.

The air inside the container body (2) circulates between the accommodation space (5) and the flow path (20) inside the refrigerator. In the internal flow path (20), the internal air is cooled by the internal heat exchanger (37). As a result, the internal air in the accommodation space (5) can be cooled, and the internal air can be adjusted to a predetermined temperature.

<Temperature sensor>
As shown in FIGS. 1 and 2, a temperature sensor (50) is attached to the casing (11). The temperature sensor (50) detects the temperature of the internal flow path (20).

As shown in FIGS. 4 to 6, the casing (11) has an opening for communicating the outside and the inside flow path (20). The opening includes a hole (13a) formed in the outer wall (13) of the refrigerator and a hole (14a) formed in the inner wall (14) of the refrigerator.

The temperature sensor (50) has a detection unit (51) and a lead wire (52). The detection unit (51) detects the temperature of the internal flow path (20). Specifically, the temperature of the internal air cooled by the internal heat exchanger (37) is detected. The lead wire (52) is connected to the detection unit (51). The lead wire (52) is composed of a conductive wire rod. The lead wire (52) is covered with an insulating coating. The lead wire (52) is flexible. An elastic member (53) is provided on the lead wire (52).

The elastic member (53) is made of a rubber material. The elastic member (53) has a large diameter portion (54) and a small diameter portion (55). The large diameter portion (54) has a larger outer diameter than the small diameter portion (55). The large diameter portion (54) is arranged closer to the detection unit (51) than the small diameter portion (55). The large diameter portion (54) has a tapered portion (56) that tapers toward the detection unit (51) side. Holes through which the lead wire (52) is inserted are formed in the large diameter portion (54) and the small diameter portion (55).

The first passage member (80) is fixed to the outer wall (13) of the refrigerator. The first passage member (80) communicates with the hole (13a) in the outer wall (13) of the refrigerator. A second passage member (60) is fixed to the inner wall (14) of the refrigerator. The second passage member (60) communicates with the hole (14a) in the inner wall (14) of the refrigerator.

After the temperature sensor (50) is inserted from the first passage member (80), the temperature sensor (50) is guided to a specific place in the internal passage member (20) by the second passage member (60). The detection unit (51) and the lead wire (52) are held by the second passage member (60).

<Second passage member>
The second passage member (60) is arranged in the internal passage (20). The second passage member (60) is made of a resin material. The second passage member (60) has a first member (61), a second member (62), and a connecting portion (63).

As also shown in FIG. 7, the first member (61) and the second member (62) are integrally formed via the bent portion (64). The first member (61), the second member (62), the connecting portion (63), and the bent portion (64) are integrally formed by resin molding.

The second passage member (60) is resin-molded in a state in which the first member (61) and the second member (62) are opened, that is, in a state before the bent portion (64) is bent. As a result, the first member (61), the second member (62), the connecting portion (63), and the bent portion (64) are integrally formed by simply releasing the resin molding mold in one direction. be able to. During resin molding, a plurality of holes (68) are formed in the first member (61) and the second member (62).

The first member (61) and the second member (62) are connected by the connecting portion (63) in a state where the bent portion (64) is bent. The connecting portion (63) is configured to engage, for example, a claw portion provided on the second member (62) side with a hole provided on the first member (61) side to connect the connecting portion (63).

An internal space (65) is formed between the first member (61) and the second member (62). A temperature sensor (50) is arranged in the internal space (65). The second passage member (60) extends from the inner wall (14) toward the partition plate (15) and then extends along the partition plate (15). For example, in FIG. 4, it extends toward the right side. The second passage member (60) extends substantially horizontally.

A flange portion (66) is provided at the base end portion of the second passage member (60). The flange portion (66) is fixed to the inner wall (14) of the refrigerator. A tip wall portion (67) is provided at the tip portion of the second passage member (60). The tip of the detection unit (51) of the temperature sensor (50) comes into contact with the tip wall (67). A hole (68) is formed in the tip wall portion (67).

The second passage member (60) constitutes a cover that covers the temperature sensor (50). A plurality of holes (68) are formed in the second passage member (60). The inner diameter of the hole (68) is 3 mm or less. The plurality of holes (68) are arranged in a zigzag pattern. Specifically, the holes (68) are arranged in a plurality of rows, and the holes (68) in one row are arranged so as to be offset by half a pitch from the holes (68) in the adjacent row. As a result, the number of holes (68) formed in the second passage member (60) can be increased, and the ventilation to the temperature sensor (50) can be improved.

Air circulates around the second passage member (60) along a predetermined distribution direction. In the example shown in FIG. 5, air flows from the upper side to the lower side of the internal flow path (20). The plurality of holes (68) are formed along the air flow direction. The plurality of holes (68) are open on the upper surface and the lower surface of the second passage member (60). As a result, air can easily flow through the hole (68) of the second passage member (60), and the ventilation to the temperature sensor (50) can be improved.

The second passage member (60) has a first guide portion (71), a curved portion (72), and a second guide portion (73). The first guide portion (71) extends from the inner wall (14) of the refrigerator toward the partition plate (15). The first guide portion (71) extends substantially horizontally. The curved portion (72) extends continuously to the first guide portion (71). The curved portion (72) is formed in a curved shape in a plan view. The curved portion (72) extends substantially horizontally.

The second guide portion (73) extends continuously and linearly to the curved portion (72). The second guide portion (73) extends in a direction perpendicular to the first guide portion (71) in a plan view. The second guide portion (73) extends along the partition plate (15). The second guide portion (73) extends substantially horizontally.

As a result, the temperature sensor (50) can be smoothly inserted along the first guide portion (71) and the second guide portion (73). The second guide portion (73) may extend in a direction forming an obtuse angle with respect to the first guide portion (71) in a plan view.

When the temperature sensor (50) is inserted from the first passage member (80), the insertion direction of the detection unit (51) is changed along the curved portion (72). As a result, the temperature sensor (50) can be arranged at a specific location in the internal flow path (20) while ensuring a distance capable of suppressing heat conduction outside the refrigerator.

The second passage member (60) has a first wall portion (70) and a second wall portion (75) in a plan view. For example, in the cross section along the temperature sensor (50) shown in FIG. 4, among the wall portions forming the contour portion of the second passage member (60), the wall portion on the side facing the partition plate (15) is the first. The wall portion on the side facing the wall portion (70) and the inner wall (14) is referred to as the second wall portion (75).

The first wall portion (70) includes a first guide portion (71), a curved portion (72), and a second guide portion (73).

The second wall portion (75) faces the first wall portion (70). The second wall portion (75) has an inclined portion (76). The inclined portion (76) is provided on a portion of the first wall portion (70) on the tip side of the curved portion (72). The inclined portion (76) is inclined so as to approach the first wall portion (70) in a plan view. This makes it easier to guide the detection unit (51) toward the tip of the second passage member (60) when the temperature sensor (50) is inserted.

The detection unit (51) is held substantially horizontally at the tip of the second passage member (60) (see FIG. 5). As a result, it is possible to prevent water from accumulating at the connection point between the detection unit (51) and the lead wire (52) in the temperature sensor (50).

<First passage member>
The first passage member (80) communicates the outside and inside passages (20). The first passage member (80) guides the temperature sensor (50) to the second passage member (60). The first passage member (80) has a passage main body (81), a flange portion (82), and a fixing portion (83).

The passage body (81) is formed in a cylindrical shape. The passage body (81) is inserted into a hole (13a) in the outer wall (13) and a hole (14a) in the inner wall (14). The tip of the passage body (81) projects into the internal passage (20). The passage body (81) is formed of a member separate from the second passage member (60). The passage body (81) and the second passage member (60) are arranged apart from each other. The tip of the passage body (81) is arranged inside the second passage member (60).

In this way, if the first passage member (80) and the second passage member (60) are separated from each other, the heat outside the refrigerator is transferred to the second passage member (60) via the first passage member (80). ) Can be suppressed. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

A tapered portion (81a) is provided on the inner peripheral edge of the end portion of the passage body (81) on the internal flow path (20) side. The diameter of the tapered portion (81a) increases toward the internal flow path (20) side. As a result, when the temperature sensor (50) is pulled out from the internal space (20), it is possible to prevent the detection unit (51) and the lead wire (52) from being caught at the end of the first passage member (80). ..

The flange portion (82) projects radially outward from the passage body (81). The flange portion (82) is in contact with the outer surface of the outer wall (13). The flange portion (82) is fixed to the outer wall (13) of the refrigerator.

The passage body (81) has a protrusion (84). The protrusion (84) is provided on the outer peripheral surface of the passage body (81). The protrusion (84) is in contact with the inner surface of the outer wall (13) of the refrigerator.

As shown in FIGS. 8 and 9, the hole (13a) in the outer wall (13) has a keyway (13b). The keyway (13b) is formed in a size that allows the protrusion (84) to pass through.

The first passage member (80) is configured to be changeable to a first position and a second position. The first position is a position where the protrusion (84) can pass through the hole (13a) of the outer wall (13) of the refrigerator (see FIG. 9). By inserting the passage body (81) into the hole (13a) in the posture of the first passage member (80), the protrusion (84) passes through the keyway (13b).

The first passage member (80) is inserted to a position where the flange portion (82) abuts on the outer wall (13) of the refrigerator. As shown in FIGS. 10 and 11, the first passage member (80) is changed from the first position to the second position by rotating the passage body (81). The second position is a position where the protrusion (84) engages with the surface of the outer wall (13) on the inner flow path (20) side (see FIG. 11). At the second position, the first passage member (80) is prevented from coming out of the hole (13a).

Thereby, by rotating the first passage member (80), the work of assembling the first passage member (80) to the outer wall (13) of the refrigerator can be easily performed. The movement from the first position to the second position is not limited to the rotational movement, and may be a parallel movement or a combination of the rotational movement and the parallel movement.

The fixed portion (83) extends outward from the flange portion (82). A fixing groove (83a) and a tapered hole (83b) are formed in the fixing portion (83). The fixing groove (83a) is formed on the outer peripheral surface of the fixing portion (83). The fixing claw (92) of the lock member (90) is fitted into the fixing groove (83a).

The tapered hole (83b) communicates with the hole in the passage body (81). The tapered hole (83b) is formed tapered from the outside of the refrigerator toward the flow path (20) inside the refrigerator. An elastic member (53) is arranged inside the tapered hole (83b). The tapered portion (56) of the elastic member (53) abuts on the tapered hole (83b).

Thereby, the airtightness between the elastic member (53) and the first passage member (80) can be ensured. Further, by inserting the temperature sensor (50) to a position where the elastic member (53) is fixed to the first passage member (80), it is possible to suppress variations in the insertion amount of the temperature sensor (50).

The elastic member (53) is fixed to the first passage member (80) by being sandwiched between the first passage member (80) and the lock member (90). The temperature sensor (50) is fixed to the first passage member (80) via the elastic member (53).

The lock member (90) has a recess (91) that is fitted into the fixing portion (83) of the first passage member (80). An insertion hole (93) is formed in the bottom surface of the recess (91). A lead wire (52) is inserted into the insertion hole (93) together with a small diameter portion (55) of the elastic member (53). A fixing claw (92) is provided on the inner peripheral surface of the recess (91). The lock member (90) is fixed to the first passage member (80) by engaging the fixing claw (92) with the fixing groove (83a) of the fixing portion (83).

<Process of arranging the temperature sensor in the flow path inside the refrigerator>
The process of arranging the temperature sensor (50) from the outside of the refrigerator to the flow path (20) inside the refrigerator by an operator will be described. As shown in FIG. 12, the first passage member (80) is fixed to the outer wall (13) of the refrigerator, and the second passage member (60) is fixed to the inner wall (14) of the refrigerator. A temperature sensor (50) is not arranged in the first passage member (80) and the second passage member (60).

As shown in FIG. 13, when the operator inserts the temperature sensor (50) from the outside of the refrigerator toward the first passage member (80), the temperature sensor (50) is detected by the curved portion (72) of the second passage member (60). The part (51) comes into contact. When the temperature sensor (50) is further inserted in this state, the tip of the detection unit (51) moves along the curved portion (72) as shown by a virtual line in FIG. As a result, the insertion direction of the detection unit (51) is changed.

As shown in FIG. 14, when the operator further inserts the temperature sensor (50), the elastic member (53) provided on the lead wire (52) is arranged inside the first passage member (80). NS. At this time, the tapered portion (56) of the elastic member (53) abuts on the tapered hole (83b) of the first passage member (80), and the position of the detection portion (51) in the second passage member (60) is positioned. It is determined.

In the example shown in FIG. 14, the position of the elastic member (53) on the lead wire (52) so that the tip portion of the detection portion (51) abuts on the tip wall portion (67) of the second passage member (60). Is set. As a result, the temperature sensor (50) can be arranged at a specific location in the interior space (20) while ensuring a distance that can suppress the conduction of heat outside the refrigerator.

FIG. 15 shows a state in which an operator is in the process of pulling out the temperature sensor (50) arranged in the second passage member (60) from the first passage member (80). The first passage member (80) is provided with a tapered portion (81a) on the inner peripheral edge of the end portion on the internal flow path (20) side. The diameter of the tapered portion (81a) increases toward the interior space (20) side.

When the operator pulls out the temperature sensor (50) from the internal flow path (20), the detection unit (51) moves along the taper unit (81a). As a result, it is possible to prevent the detection unit (51) and the lead wire (52) from being caught in the end portion of the first passage member (80).

-Effect of embodiment-
The first passage member (80) communicates the outside and the inside space (20) and guides the temperature sensor (50) to the inside space (20). The second passage member (60) is arranged on the internal space (20) side of the first passage member (80), and the temperature sensor (50) is arranged in the internal space (20). The first passage member (80) and the second passage member (60) are composed of separate members. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

The first passage member (80) and the second passage member (60) are arranged apart from each other. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

The first passage member (80) is fixed to the outer wall (13) of the refrigerator. The second passage member (60) is fixed to the inner wall (14) of the refrigerator. As a result, it is possible to suppress the conduction of heat outside the refrigerator to the temperature sensor (50).

The first passage member (80) has a passage body (81) and a protrusion (84). The first passage member (80) is configured to be changeable to a first position and a second position. The first position is a position where the protrusion (84) can pass through the hole (13a) of the outer wall (13) of the refrigerator. The second position is the position where the protrusion (84) engages with the surface of the outer wall (13) on the inner space (20) side. Thereby, the work of assembling the first passage member (80) to the outer wall (13) of the refrigerator can be easily performed.

The first position and the second position of the first passage member (80) can be changed by the rotation of the passage body (81). Thereby, by rotating the first passage member (80), the work of assembling the first passage member (80) to the outer wall (13) of the refrigerator can be easily performed.

The temperature sensor (50) has a detection unit (51) and a lead wire (52). The second passage member (60) has a curved portion (72). The curved portion (72) is formed in a curved shape in a plan view. As a result, the temperature sensor (50) can be arranged at a specific location in the interior space (20) while ensuring a distance that can suppress the conduction of heat outside the refrigerator.

<< Other Embodiments >>
In the above-described embodiment, the configuration may be as follows.

The shipping container (1) may be used for land transportation. In this case, the transportation container (1) is transported by a land transporter such as a vehicle. Specifically, the transportation container (1) is mounted on the trailer.

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. In addition, the above embodiments, modifications, and other embodiments may be appropriately combined or replaced as long as they do not impair the functions of the present disclosure. The above-mentioned descriptions of "first", "second", "third" ... Are used to distinguish the words and phrases to which these descriptions are given, and the number and order of the words and phrases are also limited. It's not something to do.

As described above, the present disclosure is useful for transport refrigeration equipment and transport containers.

1 shipping container
2 Container body
10 Transport refrigeration equipment
11 Casing
13 Exterior wall
13a hole
14 Interior wall
20 Internal flow path (internal space)
50 temperature sensor
51 Detector
52 Lead wire
60 Second passage member
72 Curved part
80 1st passage member
81 Passage body
84 protrusions

Claims (7)

A transport refrigerating device equipped with a casing (11) to be attached to the open end of the container body (2).
A temperature sensor (50) that detects the temperature of the interior space (20) and
A first passage member (80) provided in the casing (11), communicating the outside and the inside space (20) and guiding the temperature sensor (50) to the inside space (20).
A second passage member (60) arranged on the internal space (20) side of the first passage member (80) and arranging the temperature sensor (50) in the internal space (20) is provided.
A transport refrigerating device in which the first passage member (80) and the second passage member (60) are made of separate members. In claim 1,
A transport refrigerating device in which the first aisle member (80) and the second aisle member (60) are arranged apart from each other. In claim 1 or 2,
The casing (11) has an outer wall (13) facing the outside of the refrigerator and an inner wall (14) facing the inner space (20).
The first passage member (80) is fixed to the outer wall (13) of the refrigerator.
The second passage member (60) is a transport refrigerating device fixed to the inner wall (14) of the refrigerator. In claim 3,
A hole (13a) is formed in the outer wall (13) of the refrigerator.
The first passage member (80) has a passage main body (81) inserted into the hole (13a) and a protrusion (84) provided on the outer peripheral surface of the passage main body (81). The first position where the protrusion (84) can pass through the hole (13a) and the second position where the protrusion (84) engages with the surface of the outer wall (13) on the inner space (20) side. A freezing device for transportation that is configured to be repositionable. In claim 4,
The first passage member (80) is a freezing device for transportation, which is configured to be changeable between the first position and the second position by rotating the passage body (81). In any one of claims 1 to 5,
The temperature sensor (50) has a detection unit (51) for detecting the temperature of the internal space (20) and a lead wire (52) connected to the detection unit (51).
The second passage member (60) is a transport refrigerating device having a curved portion (72) formed in a curved shape in a plan view. The transport refrigerating apparatus (10) according to any one of claims 1 to 6.
A shipping container equipped with a container body (2).

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