JPH09280720A - Ventilation structure of refrigerator for container use - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ventilation structure of refrigerator for a container which can readily control the ventilating quantity while achieving an improvement of cooling efficiency and satisfying a demand for a greater ventilating quantity. SOLUTION: A casing 2 is provided with an intake opening 22 for ventilation which makes a suction side of a fan 15 communicate with an outside of a storage and a blow-off opening 23 for ventilation which makes a primary side of an evaporator 18 communicate with the outside of the storage. An outside air which is sucked through the intake opening 22 and an inside air which is obtained after circulation in the storage are mixed to form a mixture air and a part of this mixture air is blown off through the blow-off opening 23 as an exhaust gas without being subjected to a heat exchanging action by the evaporator 18 so as to ventilate the air inside the storage. Corresponding to an amount of the exhaust air which is not subjected to the heat exchange, a refrigerating action on the air used for an inside refrigeration is promoted so that a refrigerating efficiency is enhanced. Furthermore, in this case, since the intake opening 22 and the blow-off opening 23 are disposed at a position in front of the rotating direction of the fan 15 and adjacent to the fan 15, a dynamic ventilation can be realized. Furthermore, with the provision of a flow control member 25 at an upstream end of the blow-off opening 23, a ventilation amount can be increased by the dynamic ventilation, the ventilation action can be stabilized, and the ventilation amount can be readily controlled.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ventilation structure for a container refrigeration system.

[0002]

2. Description of the Related Art Conventionally, a container refrigerating device has been used for cooling the inside of a container. Ventilation means is provided because it is necessary to ventilate the air appropriately. The structure of a conventional general container refrigeration system equipped with such ventilation means,
A brief description based on FIGS. 14 to 17 is as follows.

FIG. 14 shows a front view of the refrigerating apparatus Z ₀ attached to the one end surface 1a of the container 1. This refrigerating apparatus Z ₀ is provided with a substantially rectangular plate-shaped casing 2 attached to an opening 1b provided on one end surface 1a of the container 1 so as to close the opening 1b. A concave front housing portion 3 is formed on a lower portion of a front surface 2a of the casing 2 which faces the outside of the container 1, and a pair of condensers 4, 4 and a fan 5 are provided in the front housing portion 3. , 5, a compressor 6 and a control box 7 are housed.

Also, the upper part of the rear surface 2b of the casing 2 facing the inside 1c of the container 1, that is, the front storage portion 3
Is located above the rear wall 9, the top plate 10, and the side plates 11, 11
The back storage part 8 surrounded by is formed. A plate-shaped fan guide 17 is horizontally installed at a substantially middle position in the up-down direction of the rear housing portion 8, and a pair of left and right circular opening-shaped guide portions 1 of the fan guide 17 are provided.
Fans 15 and 15 are arranged at 7a and 17a, respectively. The fan 15 is rotationally driven by a motor 14 attached to the fan guide 17 via a stay 16, and the rotation direction is the direction indicated by the wing arrow R in FIG. Further, an opening 24 is provided in a side portion of the rear storage portion 8 corresponding to the suction side of the fan 15 so that the rear storage portion 8 communicates with the inside 1 c of the container 1.

Further, at the lower position of the fan guide 17, evaporators 18 and 18 are arranged in a descending inclined state toward the casing 2 side so as to correspond to the fans 15 and 15, respectively. In addition, this evaporator 18,1
Tube plates 44, 44 are attached to the left and right ends of 8, respectively.

On the other hand, rectangular plate-shaped service lids 19 and 19 are provided on the upper portion of the casing 2 at positions corresponding to the fans 15 and 15, respectively. Of the pair of service lids 19 and 19, a pair of service lids 19 and 19 are provided. A ventilation port unit 40 is provided on the side of one of the service lids 19 and outside the tube plate 44 of the evaporator 18. The ventilation port unit 40 has an opening 24 at a portion of the rear housing portion 8 located above the fan guide 17 and the partition wall 45 following the fan guide 17 (that is, the suction side of the fan 15).
And a suction port 42 that communicates with the outside of the refrigerator via a fan, and a portion of the rear storage portion 8 that is located below the fan guide 17 and the partition wall 45 that follows the suction port 42 (that is, the fan 1).
The suction side 5) passing through the evaporator 18 and bypassing the lower side of the tube sheet 44 to the outside of the tube sheet 44 to communicate with the outside of the refrigerator, and the front surface 2a of the casing 2. The ventilation amount adjusting plate 41 is provided so as to be slidable in the up-down direction and adjusts the ventilation amount by opening and closing the suction port 42 and the air outlet 43 to an appropriate degree according to the sliding position. . The suction port 42 and the air outlet 43 are both circular openings.

In the refrigerating apparatus Z ₀ thus constructed, the cooling function and the ventilation function in the refrigerator are performed as follows. That is, when the fan 15 is operated,
Due to the suction action, the inside air A ₁ in the inside 1 c and the outside air A ₀ introduced from the suction port 42 are blown to the primary side of the evaporator 18 by the fan 15 in a mixed state, and the evaporator 18 is also blown out. All the air blown to the primary side of the air passes through the evaporator 18 and is cooled.
Then, most of the cooled air is recirculated to the inside 1c side as the cooling air A ₂ to cool the inside of the inside, and after circulating inside the inside, again as the inside air A ₁ to the fan 15 Sucked to the side.

On the other hand, the other part of the air blown to the primary side of the evaporator 18 bypasses the lower side of the tube sheet 44 and is discharged to the outside of the refrigerator as the discharge air A ₃ from the blowout port 43. To be done. Ventilation of the in-compartment air A ₁ is appropriately performed by the air discharging action from the air outlet 43 and the suction action of the outside air A ₀ from the suction port 42. In this case, since the exhaust air A ₃ is blown out from the fan 15, the exhaust air A ₃ passes through the evaporator 18 and bypasses the tube sheet 44 to flow toward the outlet port 43 side. The dynamic pressure due to the blowoff disappears and does not contribute to the ventilation effect, and the ventilation effect is performed exclusively by the static pressure difference between the inside and the outside (that is, "static pressure ventilation"). ).

The above is the outline of the structure and operation of the conventional refrigerating apparatus Z ₀ .

[0010]

However, such a conventional refrigerating apparatus Z ₀ has the following problems.

The first problem relates to cooling efficiency. That is, in this refrigerating apparatus Z ₀ , the outside air A ₀ taken in from the outside of the refrigerator and the inside air A ₁ after circulating in the inside 1 c are mixed, and all of these are passed through the evaporator 18 to be cooled,
Since a part of the cooled air is discharged to the outside of the refrigerator as the exhaust air A ₃ , the evaporator 18 performs a wasteful heat exchange action that does not contribute to the cooling action in the refrigerator, and the cooling efficiency is accordingly. Will fall.

The second problem is that of ventilation. That is, since the refrigerating apparatus Z ₀ is “static pressure ventilation” which performs ventilation by using the static pressure difference between the inside and the outside of the refrigerator as described above,
Although it is necessary to increase the capacity of the fan 15 in order to obtain a large ventilation amount, there is a certain limit to the increase of the ventilation amount because the size of the container 1 is restricted. For this reason, for example, in the case of transporting a cargo such as a bulb that is carrying out an activity of a living organism, it may happen that these required ventilation volumes cannot be sufficiently secured.

By the way, as one of the methods for solving the shortage of ventilation volume due to such "static pressure ventilation", it is conceivable to increase the ventilation volume by "dynamic pressure ventilation" utilizing, for example, fan dynamic pressure. However, in the case of dynamic pressure ventilation, since the fan dynamic pressure is directly applied to the air blown out from the outlet, it is possible to increase the ventilation volume itself, but on the other hand, the ventilation volume adjustment plate 41 opens the ventilation aperture. Degree (ie
It is the opening degree of the intake port 42 and the outlet port 43 and corresponds to the set ventilation amount) Even if it is kept constant, the actual ventilation amount is not constant to the set ventilation amount and is greatly disturbed, or the set ventilation amount is changed. Even if the opening of the ventilation opening is adjusted by the ventilation adjustment plate 41 so that the opening does not correspond to the actual ventilation, in some cases the ventilation may change more than expected due to a small opening change, On the contrary, the ventilation volume does not change much in spite of a large opening change, which causes a problem that the ventilation volume adjustment operation itself becomes difficult. Under these circumstances, "static pressure ventilation" has been widely adopted as a ventilation method for container refrigeration systems, and dynamic pressure ventilation has not been adopted.

The third problem is a problem in the ventilation volume adjusting function. That is, when the cargo stored in the container warehouse is a living thing, it is necessary to ventilate the inside of the container, but the required ventilation amount in that case is not constant, for example, life activity such as bulbs A large ventilation is required in the case of being conducted, but a small ventilation is sufficient in the case of normal vegetables and fruits, and in this case, the type of vegetables etc. within the range of small ventilation. It is required that the ventilation volume be finely adjusted according to the above.

By the way, conventionally, as shown in FIG.
Both the suction port 42 and the air outlet 43 are opened in a circular shape, and the opening areas of these are adjusted to be increased or decreased by the sliding amount of the ventilation amount adjusting plate 41 that slides, thereby adjusting the ventilation amount. Therefore, for example, from the state where both the suction port 42 and the air outlet 43 are fully closed by the ventilation amount adjusting plate 41, the ventilation amount adjusting plate 41 is slid to open the intake ports 42 and the air outlet 43. The intake port 4 is increased (that is, the set ventilation amount is increased).
2 and the air outlet 43 open from one point on the circumference while gradually increasing the chord length, so that, for example, compared with the case where both the suction inlet 42 and the air outlet 43 are rectangular openings. In the initial stage of opening (that is, in the small ventilation volume range), the increase rate of the ventilation volume with respect to the sliding volume of the ventilation volume adjusting plate 41 is low, and the fine adjustment of the ventilation volume is easy. This point can be said to be a ventilation volume adjustment function suitable for transportation of ordinary vegetables, fruits and the like, which requires a small required ventilation volume and fine adjustment of the ventilation volume.

However, when the ventilation amount adjusting plate 41 is slid to the maximum position and the suction port 42 and the air outlet 43 are fully opened, the suction port 42 and the air outlet 43 are circular openings. Therefore, for example, compared with the case where this is a rectangular opening, the opening area of the suction port 42 and the air outlet 43 is small compared to the sliding amount of the ventilation amount adjusting plate 41, and the maximum ventilation amount is sufficiently secured. It is difficult to do so, and it becomes a problem especially when a large ventilation is required such as when transporting bulbs.

Further, when the ventilation amount adjusting plate 41 is slid to change the suction port 42 and the air outlet 43 from the fully closed state to the fully opened state, the ventilation amount adjusting plate 41 is closed in the vicinity of these half open states. The change in the opening amount (that is, the ventilation amount) of the suction port 42 and the blowout port 43 with respect to the change in the slide amount becomes extremely large, and it becomes very difficult to finely adjust the ventilation amount in the half open state.

From the above, when adjusting the ventilation amount, it is easy to finely adjust the ventilation amount in the initial stage of opening the inlet 42 and the outlet 43, and in the fully opened state, the opening area is as large as possible. Is required, and in the intermediate stage between them, the operating characteristics are required so that the opening amounts of the suction port 42 and the air outlet 43 change in proportion to the change of the sliding amount of the ventilation amount adjusting plate 41. It is what is done.

Therefore, the invention of the present application has been made as a proposal of a ventilation structure for a container refrigerating apparatus which can realize both improvement of cooling efficiency, response to demand for increase in ventilation amount, and easy adjustment of ventilation amount. .

[0020]

Means for Solving the Problems In the present invention, the following configuration is adopted as specific means for solving such problems.

In the first invention of the present application, the condenser 4 is installed in the lower part of the front surface 2a side of the casing 2 which is attached to the opening 1b provided in the container 1 so as to close the opening 1b and faces the outside of the case. The evaporator 18 on the upper side of the rear surface 2b facing the
While each is arranged, a fan 15 is arranged above the evaporator 18, and the fan 15 allows the air in the refrigerator to flow from the primary side above the evaporator 18 toward the secondary side below. In the container refrigeration apparatus thus obtained, the casing 2 is provided with a ventilation suction port 22 for communicating the suction side of the fan 15 with the outside of the refrigerator, and a ventilation chamber for communicating the primary side of the evaporator 18 with the outside of the refrigerator. Outlet 23 for
Are formed respectively.

According to a second invention of the present application, in the ventilation structure for a container refrigerating apparatus according to the first invention, the suction port 22 and the blowout port 23 are on the front side in the rotation direction of the fan 15 and at the fan 15. The airflow blown from the fan 15 from the fan 15 so as to cover at least a portion of the air outlet 23 close to the fan 15 near the upstream end of the air outlet 23. A flow control member 25 for controlling the blown air flow so that the air flows in a detoured state without flowing in a short circuit to the air outlet 23 side.
It is characterized by having provided.

In the third invention of the present application, the above-mentioned first or second
In the ventilation structure for a container refrigerating apparatus according to the invention, both the suction port 22 and the blowout port 23 have a rectangular opening shape and are arranged so as to straddle the suction port 22 and the blowout port 23. Specific opening edge 2 of inlet 22 and outlet 23
2a, 23a is movable in a direction substantially parallel to the first
At the moving position, both the suction port 22 and the blow-out port 23 are covered and fully closed, and at the second moving position, the suction port 22 and the blow-out port 23 are both opened to make them fully open. It is characterized in that the ventilation area adjusting plate 21 is configured to increase and decrease its opening area.

According to a fourth invention of the present application, in the ventilation structure for a container refrigerating apparatus according to the third invention, the ventilation amount adjusting plate 21 of the opening edges of the suction port 22 and the air outlet 23 is the same. The rear opening edge 22 located on the rear side in the moving direction from the first moving position to the second moving position side
It is characterized in that b and 23b are slanting edges having a predetermined slanting angle with respect to the direction orthogonal to the moving direction of the ventilation amount adjusting plate 21.

[0025]

According to the present invention, the following effects can be obtained by adopting such a configuration.

According to the ventilation structure of the container refrigerating apparatus of the first invention of the present application, the casing 2 has a suction inlet 22 for communicating the suction side of the fan 15 with the outside of the refrigerator, and the evaporation. Since the ventilation outlets 23 that communicate between the primary side of the container 18 and the outside of the refrigerator are respectively formed, mixed air of the outside air sucked from the suction port 22 and the inside air after circulating inside the refrigerator. A part of the air is blown out from the air outlet 23 to the outside of the refrigerator as exhaust air before being subjected to the heat exchange action in the evaporator 18, whereby the inside of the refrigerator is ventilated. Therefore, as compared with the conventional container refrigerating device that discharges a part of the air after heat exchange as the exhaust air to the outside of the refrigerator, the inside of the refrigerator is cooled by the amount that the heat of the exhaust air is not exchanged in the evaporator 18. The cooling action on the air involved is promoted, and the cooling efficiency is improved accordingly.

According to the ventilation structure of the container refrigerating device of the second invention of the present application, firstly, first, the suction port 22 and the blowout port 23 are located on the front side in the rotation direction of the fan 15 and in the fan 15. By providing it in a position close to
Since "dynamic pressure ventilation" in which the dynamic pressure of the fan 15 is applied to the exhaust air discharged from the air outlet 23 is realized, the fan capacity can be increased as in the case of the conventional "static pressure ventilation". Needless to say, the discharge of air from the air outlet 23 is promoted, and the ventilation amount can be easily increased.

Secondly, in the vicinity of the upstream end of the air outlet 23, at least a portion of the air outlet 23 close to the fan 15 is blown by the air flow blown from the fan 15 from the fan 15. Since the flow control member 25 for controlling the blown air flow is provided on the outlet 23 side so as not to flow in a short-circuited manner but to flow in a detoured state, the fan dynamic pressure becomes excessive in the exhaust air blown from the blowout port 23. It is prevented from acting. As a result, the disturbance of the ventilation volume is prevented as much as possible, and the set ventilation volume can be maintained, and the correlation between the ventilation opening and the ventilation volume is maintained almost constant, and ventilation by adjusting the ventilation opening is performed. It is possible if the amount adjustment operation is easy.

Therefore, according to the ventilation structure of the refrigerating apparatus for containers according to the second aspect of the present invention, the effect of increasing the ventilation volume by the "dynamic pressure ventilation" is obtained in addition to the effect of "improving the cooling efficiency" described above. In addition, the disturbance of the ventilation volume and the difficulty of adjusting the ventilation volume due to the adoption of the "dynamic pressure ventilation" can be eliminated, and the ventilation volume can be stabilized and the ventilation volume adjustment can be facilitated.

According to the ventilation structure for the container refrigerating apparatus of the third invention of the present application, the following effect is obtained in addition to the effect described above or. That is, in the present invention, both the suction port 22 and the blowout port 23 have a rectangular opening shape, and are arranged so as to straddle the suction port 22 and the blowout port 23, and the suction port 22 and the blowout port 23 are arranged. Is movable in a direction substantially parallel to the specific opening edges 22a and 23a, and at its first moving position, it covers both the suction port 22 and the blowout port 23 to bring it into a fully closed state, and at the second moving position. Is configured to open and close both the suction port 22 and the blow-out port 23 so that the opening area is increased or decreased by the ventilation amount adjusting plate 21 that fully opens them.
When the air outlet 23 and the air outlet 23 are fully opened, the ventilation volume adjusting plate 2
A large opening area corresponding to the movement amount of 1 is secured, and the maximum ventilation amount is increased compared to the case where the suction port 22 and the blow-out port 23 are circular openings, especially for bulbs and the like. It is suitable for containers used for transportation of cargo requiring a large ventilation volume.

According to the ventilation structure of the container refrigerating apparatus of the fourth invention of the present application, the following effects can be obtained in addition to the effects described above. That is, in this invention,
Of the opening edges of the suction port 22 and the air outlet 23, rear opening edges 22b, 23b located on the rear side in the moving direction of the ventilation amount adjusting plate 21 from the first moving position to the second moving position side. Is an inclined edge having a predetermined inclination angle with respect to the direction orthogonal to the moving direction of the ventilation amount adjusting plate 21, so that the ventilation amount adjusting plate 21 is moved so that the suction port 22 and the outlet port 23 are moved. When opening, in the initial stage of the opening (that is, in the range of small ventilation volume), the suction port 22 and the outlet port 23 are inclined to the rear opening edges 22b and 23b as the ventilation volume adjusting plate 21 moves. The opening areas of the suction port 22 and the air outlet 23 increase with respect to changes in the moving amount of the ventilation amount adjusting plate 21, and the increase ratio of the opening areas is suppressed low. Therefore, in this small ventilation range, fine adjustment of the ventilation becomes easy, and the ventilation is suitable especially for containers that are used for the transportation of normal vegetables, etc., where the required ventilation is small but fine adjustment is required. Characterized.

On the other hand, after the suction port 22 and the air outlet 23 are opened to the entire area of the rear opening edges 22b and 23b, respectively, the suction port 22 and the air outlet 23 are moved along with the movement of the ventilation amount adjusting plate 21. The opening is expanded in a rectangular shape while expanding the opening area, and finally the maximum opening is reached. Therefore, in this area, the opening areas of the suction port 22 and the air outlet 23 change in proportion to the change of the movement of the ventilation amount adjusting plate 21, so that the ventilation amount adjustment by the operation of the ventilation amount adjusting plate 21 is easy. Further, at the maximum opening degree, a large opening area corresponding to the moving amount of the ventilation amount adjusting plate 21 is secured, and compared with a case where the suction port 22 and the blowout port 23 are circular openings, for example. The maximum ventilation volume is increased, and it is particularly suitable for a container used for transportation of cargo such as bulbs that requires a large ventilation volume.

[0033]

BEST MODE FOR CARRYING OUT THE INVENTION The ventilation structure for a container refrigerating apparatus of the present invention will be specifically described below with reference to a preferred embodiment.

First Embodiment FIGS. 1 to 4 show a refrigerating apparatus Z for a container which is a first embodiment of the ventilation structure of the present invention. The basic structure of the refrigerating apparatus Z is as follows. because it is similar to the conventional refrigeration system Z ₀ described above, description thereof is omitted duplicate the same reference numerals and the same constituent members as a conventional refrigeration system Z ₀ was subjected to FIGS. 11 to 14 Only the configuration different from the conventional refrigeration system Z ₀ will be described in detail.

As will be described below, this refrigerating machine Z is different from the conventional refrigerating machine Z _{0 in} the structure of the part related to ventilation.

The first peculiar structure is the ventilation unit 20.
The present invention relates to the structure and the formation position of the suction port 22 and the blowout port 23 that constitute the.

That is, in the refrigerating apparatus Z in this embodiment, both the suction port 22 and the air outlet 23 are rectangular openings, and the suction port 22 and the air outlet 23 are provided in the upper part of the casing 2. It is directly provided on one of the pair of left and right service lids 19, 19. Further, the formation positions of the suction port 22 and the blowout port 23 in the vertical direction are such that the suction port 22 is located above the fan guide 17 (that is, the suction side of the fan 15) and the blowout port 23 is located above the fan. The middle of the guide 17 and the evaporator 18 located below the guide 17 (that is, the evaporator 18
It is set to be located on the primary side). As shown in FIG. 3, the relative positions of the suction port 22 and the blowout port 23 with respect to the fan 15 are such that the suction port 22 and the blowout port 23 both have a peripheral edge of the fan 15 on the front side in the rotation direction of the fan 15. It is set to be close to. Therefore, the fan dynamic pressure effectively acts on the air blown from the fan 15 toward the evaporator 18 side and flowing to the blowout port 23.

Further, the outer plate 19a of the service lid 19 is used.
A ventilation amount adjusting plate 21 that adjusts the ventilation amount by adjusting the opening area of these inlets 22 and the outlets 23 on the downstream side of the outlets 23 is arranged. As shown in FIG. 5 to FIG. 7, the ventilation amount adjusting plate 21 is arranged along the outer plate 19a of the service lid 19 in the vertical direction (that is, one of the suction ports 22 located on substantially the same line in the vertical direction). The opening edge 22a and one opening edge 23 of the air outlet 23
It is composed of a plate-like body that is slidable in a direction (parallel to a), and the suction port 22 is provided at the lowermost moving position (corresponding to the “first moving position” in the claims) shown in FIG. And the air outlet 23 can be fully closed at the same time, and two openings 26, 2 are provided at the intermediate position in the sliding direction.
7 are formed at predetermined intervals in the vertical direction. Therefore, as shown in FIG. 6, when the ventilation amount adjusting plate 21 is set to the intermediate position, a part of the suction port 22 overlaps with the opening 26 as shown by hatching in FIG. The opening 22 is half-opened, and the air outlet 23 extends off the ventilation amount adjusting plate 21 and is half-opened (the ventilation opening is half-opened). Further, as shown in FIG. 7, in the state where the ventilation amount adjusting plate 21 is set to the uppermost moving position (corresponding to the “second moving position” in the claims), it is hatched in FIG. At the same time, the suction port 22 is overlapped with the opening 26 and the opening 27 at the same time to fully open the suction port 22, and the entire area of the blowout port 23 protrudes from the ventilation amount adjusting plate 21 and is fully opened (ventilation). Fully open mouth).

As shown in FIG. 3, the service lid 19 has a double structure of an outer plate 19a and an inner plate 19b, and both the suction port 22 and the air outlet 23 are the service lid 1.
9 is formed of a tubular body penetratingly arranged in the plate thickness direction, one end of which is opened on the outer plate 19a, and the other end thereof is the back face storage portion 8
It opens to face.

The second peculiar structure relates to a structure for preventing the fan dynamic pressure from excessively acting on the air outlet 23.

That is, in this embodiment, the flow control member 25 as described below is arranged at the upstream end of the outlet 23. As shown in FIG. 8, the flow control member 25 includes an upper wall 25a along the upper edge of the outlet 23 and one side edge of the outlet 23 (specifically, on the rear side in the rotation direction of the fan 15). A side wall 25b along the side edge) and a front wall 25c having a substantially triangular plate shape that straddles the upper wall 25a and the side wall 25b, and has a shape obtained by dividing a rectangular casing into two at diagonal positions thereof. ing. The flow control member 25 has its opening side facing downward and the upper wall 25
A is attached to the upper edge of the outlet 23 and the side wall 25b is attached to the upstream end of the outlet 23 with the side wall 25b along the side edge of the outlet 23. Therefore, by attaching the flow control member 25 to the blower outlet 23, the fan 1
The flow control member 25 covers the upper half portion of the diagonal line 5 in the rearward direction of rotation.

By providing such a ventilation structure, in the refrigeration system Z of this embodiment, the following unique ventilation action can be obtained as compared with the conventional refrigeration system.

That is, in the refrigerating apparatus Z of this embodiment, the casing 2 is provided with a suction inlet 22 for communicating the suction side of the fan 15 with the outside of the refrigerator, and the evaporator 18.
Since the ventilation outlets 23 for communicating between the primary side of the container and the outside of the refrigerator are respectively formed, the outside air A ₀ sucked from the suction port 22 and the inside air A ₁ after circulating inside the refrigerator are formed. Before a part of the mixed air is subjected to the heat exchange action in the evaporator 18, the mixed air is blown out from the air outlet 23 as the exhaust air A ₃ to the outside of the refrigerator. Therefore, for example, as compared with the conventional refrigerating apparatus Z ₀ that discharges a part of the air after heat exchange as the exhaust air to the outside of the refrigerator, the inside of the refrigerator is cooled by the amount that the heat of the exhaust air is not exchanged in the evaporator 18. The cooling effect on the air involved is accelerated,
The cooling efficiency can be improved by that much.

Further, in the refrigerating apparatus Z of this embodiment, the suction port 22 and the air outlet 23 are connected to the fan 1
"Dynamic pressure ventilation" in which the dynamic pressure of the fan 15 acts on the exhaust air discharged from the air outlet 23 is provided by being provided on the front side in the rotation direction of 5 and close to the fan 15. Therefore, for example, without increasing the fan capacity as in the case of the conventional "static pressure ventilation", it is possible to accelerate the discharge of air from the blow-out port 23 by the fan dynamic pressure, and increase the ventilation amount. That is, it is possible to improve the ventilation capacity. Therefore, even in the case of transporting, for example, a bulb or the like that requires a larger amount of ventilation, this can be easily dealt with, and the versatility of the refrigerating apparatus Z is improved accordingly.

However, if the "dynamic pressure ventilation" is simply adopted, the influence of the fan dynamic pressure on the exhaust air A ₃ blown out from the air outlet 23 becomes excessive, which causes the disturbance of the ventilation volume or the difficulty of adjusting the ventilation volume. As mentioned above, there is a possibility that this problem may occur.

However, the refrigerating apparatus Z of this embodiment
In the above, by providing the flow control member 25 at the upstream end of the air outlet 23, the problems as described above are solved, and while the advantages of "dynamic pressure ventilation" are maximized, the ventilation volume is stabilized at the same time. It is possible to realize the realization and the ease of ventilation volume adjustment. That is, by providing the flow control member 25 at the upstream end of the outlet 23, the portion of the outlet 23 near the fan 15 is covered, and the air flow blown out from the fan 15 is discharged from the fan 15. It flows into the outlet 23 side while colliding with the walls 25a, 25b, 25c of the flow control member 25 and circumventing the wall 25a, 25b, 25c without short-circuiting to the outlet 23 side. Thus exhaust air A ₃ by detour state the influence of the fan dynamic pressure to air A ₃ out exhaust by flowing through the air outlet 23 side is reduced moderately, as a result,
Disturbance of the ventilation amount corresponding to the amount of air discharged through the outlet 23 is prevented as much as possible, the ventilation amount is stably secured, and the set ventilation amount can be maintained.

Further, as described above, the flow control member 25
As a synergistic effect that the ventilation volume is stabilized by the addition of the above and that both the suction port 22 and the blowout port 23 are rectangular openings, the correlation between the ventilation opening degree and the ventilation volume is maintained substantially constant. It Specifically, as shown in the test results shown in FIG. 10, when the flow control member 25 is not provided, the "ventilation opening degree-ventilation rate" characteristic is greatly bent, and the rate of change of the ventilation rate with respect to the ventilation opening degree is increased. Although there is a portion that rapidly increases and a portion that hardly changes, when the flow control member 25 is provided, the "ventilation opening degree-ventilation amount" characteristic becomes substantially linear, and the ventilation opening degree and the ventilation amount There is a proportional relationship between them. Therefore, in the refrigerating apparatus Z of this embodiment including the flow control member 25, when adjusting the ventilation amount according to the type of cargo to be transported, how much ventilation should be set at what ventilation opening. Knowing that you can get the amount,
Ventilation control becomes extremely easy.

Here, the "ventilation opening degree" is indicated by the operation amount of the ventilation amount adjusting plate 21 of the ventilation port unit 20.

Further, FIG. 9 shows a modification of the flow control member 25 shown in FIG. The flow control member 25 of this modified example includes an upper wall 25a and a pair of left and right side walls 25b, 2b.
5b and a rectangular front wall 25c, and by attaching the flow control member 25 to the air outlet 23, the air outlet 23 is entirely covered by the flow control member 25. The above-mentioned fan 15 through only the lower surface side
Will face. Therefore, the influence of the fan dynamic pressure can be further reduced as compared with the case of the flow control member 25 in the above embodiment.

Second Embodiment FIGS. 11 and 13 show a ventilation port unit 20 portion in a second embodiment of the ventilation structure for a container refrigerating apparatus according to the present invention. In addition, the ventilation structure of the container refrigerating apparatus in the second embodiment is different from the ventilation structure in the first embodiment only in the structure of the ventilation port unit 20, and the other configurations are the same. Therefore, here, only the part of the ventilation port unit 20 peculiar to the second embodiment will be described in detail, and the description of the first embodiment will be referred to for the configuration and operational effects of the other parts.

The ventilation port unit 20 has a suction port 22 and a blow port 23 which are opened on the service lid 19 and are described below.
And a ventilation amount adjusting plate 21 for adjusting the ventilation amount by adjusting the opening areas of the suction port 22 and the air outlet 23.

The suction port 22 and the air outlet 23 have the first
Similarly to the suction port 22 and the air outlet 23 in the above embodiment, a rectangular opening is basically used, and the lower opening edges 22b, 2 are provided.
3b (corresponding to the "rear opening edge" in the claims), one opening edge 22a, 2 extending in the vertical direction
3a (each corresponding to a "specific opening edge" in the claims) is an inclined edge inclined at a predetermined inclination angle with respect to a direction orthogonal thereto.

The ventilation amount adjusting plate 21 is slidable in the vertical direction along the surface of the service lid 19 (that is, in the direction parallel to the opening edges 22a and 23a of the suction port 22 and the air outlet 23). It is composed of a plate-like body, and has an opening 26 at the vertical middle position. The ventilation amount adjusting plate 21 has a lowermost moving position shown in FIG. 11 (corresponding to a “first moving position” in the claims) and an uppermost moving position shown in FIG. 13 (in the claims). (Corresponding to the "second moving position") is vertically slid, the suction port 22 and the outlet 23 are fully closed at the lowest moving position, and the outlet 23 is moved at the uppermost position. It comes off and it is fully opened and the opening 2
6 is overlapped with the blow-out port 23 so that it is fully opened. In addition, in FIG. 12 and FIG.
The opened portions of the suction port 22 and the air outlet 23 are hatched.

According to the ventilation structure of the container refrigerating apparatus of the second embodiment, the opening edge of each of the suction port 22 and the outlet port 23 is moved from the lowermost moving position of the ventilation amount adjusting plate 21 to the uppermost position. Since the opening edges 22b and 23b located on the rear side (that is, the lower side) in the moving direction to the moving position side (that is, the upward opening operation direction) are inclined edges,
When the ventilation volume adjusting plate 21 is moved to open the suction port 22 and the air outlet 23, in the initial stage of opening (that is, a range of small ventilation volume), the ventilation volume adjusting plate is opened. With the movement of 21, the suction port 22 and the air outlet 23 gradually open along the inclination of the opening edges 22b, 23b, and the suction port 22 and the air outlet are changed with respect to the change in the movement amount of the ventilation amount adjusting plate 21. The increase rate of the opening area of 23 can be suppressed low. Therefore, in this small ventilation range, fine adjustment of the ventilation becomes easy, and the ventilation is suitable especially for containers that are used for the transportation of normal vegetables, etc., where the required ventilation is small but fine adjustment is required. The characteristics are obtained.

On the other hand, after the suction port 22 and the air outlet 23 are opened to the entire areas of the respective opening edges 22b and 23b, the suction port 22 and the air outlet 23 are moved along with the movement of the ventilation amount adjusting plate 21. The opening is expanded into a rectangular shape while expanding the opening area, and finally the maximum opening is obtained as shown in FIG. Therefore, in this operating range, the suction port 22 and the air outlet 2 are changed as the movement of the ventilation amount adjusting plate 21 changes.
Since the opening area of 3 changes proportionally, the ventilation volume adjusting plate 2
Ventilation amount adjustment by operation 1 becomes easy. Further, when the maximum opening is set, the ventilation volume adjusting plate 21
A large opening area corresponding to the moving amount of the air is secured, and the maximum ventilation is increased compared to the case where the suction port 22 and the air outlet 23 are circular openings. It is suitable as a ventilation structure for containers used for the transportation of cargo requiring ventilation.

[Brief description of drawings]

FIG. 1 is a front view showing a first embodiment of a ventilation structure for a container refrigeration system of the present invention.

FIG. 2 is an enlarged view of the II section of FIG. 1 from the back side.

FIG. 3 is a view on arrow III-III in FIG.

FIG. 4 is a view taken in the direction of arrows IV-IV in FIG. 2;

5 is an explanatory view of a ventilation amount adjustment state of the ventilation port unit shown in FIG.

FIG. 6 is an explanatory view of a ventilation amount adjustment state of the ventilation port unit shown in FIG.

7 is an explanatory view of a ventilation amount adjustment state of the ventilation port unit shown in FIG.

FIG. 8 is an enlarged perspective view of the dynamic pressure preventing member shown in FIG.

FIG. 9 is a perspective view showing a modified example of the dynamic pressure prevention material.

FIG. 10 is a characteristic diagram of “ventilation opening degree-ventilation amount”.

FIG. 11 is a front view of a ventilation port unit portion in a second embodiment of the ventilation structure for a container refrigeration system of the present invention.

12 is an explanatory view of a ventilation amount adjustment state of the ventilation port unit shown in FIG.

13 is an explanatory view of a ventilation amount adjustment state of the ventilation port unit shown in FIG.

FIG. 14 is a front view of a container refrigerating apparatus having a conventional ventilation structure.

15 is an enlarged view of the XV portion of FIG. 14 from the back side.

16 is a view taken along the line XVI-XVI in FIG.

FIG. 17 is a view on arrow XVII-XVII in FIG. 15.

[Explanation of symbols]

1 is a container, 2 is a casing, 3 is a front storage unit, 4 is a condenser, 5 is a fan, 6 is a compressor, 7 is a control box, 8 is a rear storage unit, 9 is a rear wall, 10 is a top plate, 1
1 is a side plate, 12 is a partition, 14 is a motor, 15 is a fan,
16 is a stay, 17 is a fan guide, 18 is an evaporator, 1
9 is a service lid, 20 is a ventilation port unit, 21 is a ventilation amount adjusting plate, 22 is a suction port, 23 is an air outlet, 24 is an opening, 2
5 is a flow control member, and 26 and 27 are openings.

Claims (4)

[Claims] 1. An opening (1b) provided in a container (1)
The condenser (4) is attached to the lower part of the front surface (2a) side facing the outside of the casing (2) mounted so as to close the opening (1b) and the upper part of the rear surface (2b) side facing the inside of the chamber is evaporated. While the vaporizers (18) are arranged respectively, the vaporizer (1
The fan (15) is arranged above the fan (8) and the fan (1)
5) In the container refrigerating device, which allows the internal air to flow through from the primary side located above the evaporator (18) to the secondary side located below the evaporator (18) in the casing (2). A ventilation suction port (22) that communicates the suction side of the fan (15) with the outside of the refrigerator, and a ventilation outlet (23) that communicates the primary side of the evaporator (18) with the outside of the refrigerator. Ventilation structure for refrigeration equipment for containers characterized by being formed respectively. 2. The suction port (22) and the air outlet (23) according to claim 1, wherein the suction port (22) and the air outlet (23) are provided on a front side in a rotation direction of the fan (15) and in a position close to the fan (15). An air flow blown from the fan (15) near the upstream end of the air outlet (23) covers at least a portion of the air outlet (23) near the fan (15) and is blown from the fan (15). A ventilation structure for a container refrigeration system, characterized in that a flow control member (25) is provided on the side of the outlet (23) so as to control the blown air flow so as to flow in a detoured state without short-circuiting. 3. The suction port (22) and the air outlet (23) according to claim 1 or 2, wherein both the air inlet (22) and the air outlet (23) have a rectangular opening shape and straddle the air inlet (22) and the air outlet (23). And the suction port (22) and the air outlet (2
3) is movable in a direction substantially parallel to the specific opening edges (22a) and (23a), and covers the suction port (22) and the air outlet (23) together at the first moving position. Fully closed, the suction port (22) at the second moving position
Of the refrigerating apparatus for containers characterized in that the opening area of the container is increased or decreased by a ventilation amount adjusting plate (21) for opening both the air outlet and the air outlet (23) to fully open them. Ventilation structure. 4. The method according to claim 3, wherein the ventilation amount adjusting plate (21) is moved from the first moving position to the second moving position of the opening edges of the suction port (22) and the air outlet (23). The rear opening edges (22b) and (23b) located on the rear side in the moving direction of the are the inclined edges having a predetermined inclination angle with respect to the direction orthogonal to the moving direction of the ventilation amount adjusting plate (21). Ventilation structure of refrigeration equipment for containers characterized by being.