JPH1163768A - Refrigerated container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the defrosting efficiency of a refrigerated container. SOLUTION: In a refrigerated container including a refrigeration unit comprising a compressor 4, a condenser 5 having an outer fan 6, and an evaporator 7 having an inner fan 8, a reheat-exchanger 17 being supplied with delivery gas coolant (i.e., hot gas) from the compressor 5 through the condenser 5 is disposed while abutting on the lower surface of the evaporator 7. At the time of defrost operation, the delivery gas coolant (i.e., hot gas) is supplied to the evaporator 7 through the reheat-exchanger 17. Consequent, the lower surface of the evaporator 7 is thermally defrosted by the delivery gas coolant (i.e., hot gas) supplied to the evaporator 7 and further defrosted thermally through heat conduction from the reheat-exchanger 17 being supplied with delivery gas coolant (i.e., hot gas).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a refrigeration container, and more particularly to a structure for improving the defrosting efficiency of a refrigeration container having a reheating function.

[0002]

2. Description of the Related Art A general refrigeration container is used for storing articles (that is, stored articles).
A container body for storing the article to be frozen), a condenser provided with a compressor, an external fan, and an evaporator provided with an internal fan, which are provided on the front side of the container main body to cool the inside of the container main body. And a refrigeration unit provided to guide the cold air obtained by the refrigeration unit (that is, the cool air blown out through the evaporator) to the bottom of the container body.

[0003] In the case of storing items that need to be stored at low humidity, such as bulbs, in a refrigerated container having the above configuration, the air that has been cooled and dehumidified by an evaporator is reheated to obtain a relative humidity. Is to be blown out into the refrigerator in a state where is lowered.

A method of arranging an electric heater on the downwind side of the evaporator for the reheating has been conventionally adopted.

However, when an electric heater is used to reheat air blown into the refrigerator as described above, the following problems occur.

[0006] The electric heater requires regular maintenance and extra input for the electric heater.

The surface temperature of the electric heater is high (for example,
(About 250 ° C.), the drain water of the evaporator may re-evaporate on the heater surface, and humidify the blown air.

[0008] A protection device for the electric heater is required, and maintenance of the protection device is also required.

Due to the structure, a sufficient contact area with the blown air cannot be obtained, resulting in poor efficiency.

[0010] Since the electric heater is thermally deformed when heated and not heated, the mounting structure needs to have elasticity.
The mounting structure becomes complicated.

[0011]

As a solution to the above-mentioned problem when an electric heater is used, a discharge gas refrigerant (that is, hot gas) discharged from a compressor is provided in a refrigerant flow path in an evaporator. There has been proposed a type in which a condenser is supplied by a bypass and a part of the evaporator is made to function as a reheat heat exchanger for reheating blown air (for example, see JP-A-8-285390). ).

However, the above-mentioned known example has a structure in which the discharged gas refrigerant (ie, hot gas) is merged in the middle of the refrigerant flow path in the evaporator. In order to reduce the pressure, a throttle mechanism different from the throttle mechanism for the evaporator is required, and the effect of heat conduction from the part acting as the evaporator in the part acting as the reheat heat exchanger Easier to receive.

Further, in the case of the refrigeration container having the above structure, since air is supplied downward to the evaporator, the supply of the refrigerant to the evaporator is performed from the lower surface side so that the flow of the refrigerant and the flow of the air are countercurrently. By doing so, the cooling capacity is improved. However, with such a configuration, when moisture in the air frosts, much frost forms on the lower surface side of the evaporator. When the frost reaches the limit, a defrosting operation of melting the frost by supplying the discharge gas refrigerant (that is, hot gas) of the compressor to the evaporator is performed. There is a problem that it is difficult to completely melt the frost and the defrosting efficiency is not improved.

The present invention has been made in view of the above points, and has as its object to improve the defrosting efficiency of a refrigeration container.

[0015]

According to the present invention, as a means for solving the above-mentioned problems, a container body 1 for storing articles to be stored and a container body 1 arranged on the front side of the container body 1 to cool the inside of the container body 1 are provided. And a refrigeration unit provided with a compressor 4, a condenser 5 provided with a fan 6 outside the refrigerator and an evaporator 7 provided with a fan 8 inside the refrigerator, on the leeward side of the evaporator 7. A reheat heat exchanger 17 to which the gas refrigerant discharged from the compressor 4 (that is, hot gas) is supplied by way of the condenser 5 is provided in contact with the lower surface of the evaporator 7 and defrosted. During operation, the discharge gas refrigerant (that is, hot gas) is supplied to the evaporator 7 via the reheat heat exchanger 17.

With the above configuration, during the defrosting operation, the discharge gas refrigerant (that is, hot gas) is supplied to the evaporator 7 via the reheat heat exchanger 17, so that the evaporator 7 Is heated and melted by the discharge gas refrigerant (that is, hot gas) supplied to the evaporator 7, and the reheat heat is supplied to the discharge gas refrigerant (that is, hot gas). Heat frost is also caused by heat conduction from the exchanger 17. Therefore, the frost on the lower surface side of the evaporator 7, which has conventionally been difficult to completely melt, can be completely melted, and the defrosting efficiency can be greatly improved.

As described in the second aspect of the present invention, the reheat heat exchanger 17 is connected to the proportional valve 13 from the inlet side of the condenser 2.
In the bypass circuit 38 which branches through the drain pan heater 37 and reaches the inlet side of the evaporator 7, the bypass circuit 38 is provided upstream of the drain pan heater 37, and the bypass circuit 38 is provided with a dehumidifying operation and a defrosting operation. During operation, the discharge gas refrigerant (that is, hot gas) is supplied to the reheat heat exchanger 17, and during other operations, the reheat heat exchanger 17 and the drain pan heater 37 are bypassed to evaporate. When a three-way valve 40 that switches the refrigerant flow direction so as to supply the refrigerant to the inlet side of the heater 7 is provided,
Supplying the discharged gas refrigerant (that is, hot gas) to the reheat heat exchanger 17 during the defrosting operation using an existing circuit for supplying the discharged gas refrigerant (that is, hot gas) to the refrigerant 7 Thus, the defrosting efficiency can be improved without complicating the circuit configuration.

[0018]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 3, the refrigeration container has a container body 1 for storing articles to be stored and a refrigeration unit disposed on the front side of the container body 1 for cooling the inside of the container body 1. 2 is provided.

The refrigeration unit 2 is provided with a compressor 4 and a condenser 5 which are provided outside of a casing 3 of a casing 3 provided on the front side of the container main body 1 and which have a fan 6 outside the refrigerator.
And an evaporator 7 provided with an in-compartment fan 8 disposed inside the casing 3. Reference numeral 9 denotes an air suction port for sucking air in the container body 1 into the refrigeration unit 2, 10 denotes a drain pan disposed below the evaporator 7, and 11 denotes a flow divider.

The cool air blown out of the evaporator 6 is supplied to the rear ducts 12, 12,... Located on the leeward side of the evaporator 7 (specifically, below the drain pan 10) inside the storage of the casing 3. A large number of cold air passages 14, 14... Formed in the bottom of the container body 1 through side ducts 13, 13 located on both sides of the back duct 12.
, And is blown out through the entire area of the container body 1 through the cold air passages 14, 14,. Reference numeral 15 denotes a partition member that also serves as a reinforcing member of the casing 4, and reference numeral 16 denotes a service door.

On the lower surface of the evaporator 7, the gaseous refrigerant discharged from the compressor 4 (ie, hot gas) is supplied on the leeward side of the evaporator 7, bypassing the condenser 5. A reheat heat exchanger 17 is mounted. The reheat heat exchanger 17 has a function of reducing the relative humidity by reheating the blown air cooled and dehumidified in the evaporator 7.

As shown in FIGS. 4 to 6, the evaporator 7 is composed of a large number of plate-like fins 19, 19,. It is composed of a cross-fin coil type heat exchanger, and has tube sheets 20, 20, 20 at both ends in the longitudinal direction and an intermediate portion.

On the other hand, the reheat heat exchanger 17 is of a cross fin coil type comprising a large number of plate-like fins 22, 22... , Having tube sheets 23, 23, 23 at both ends in the longitudinal direction and an intermediate portion, and reinforcing tube sheets 24, 2 at an intermediate portion of these tube sheets 23, 23, 23.
4 are provided. And the tube sheets 23, 23, 2
3 and the both ends of the reinforcing tube sheets 24, 24 are connected by flat reinforcing plates 25, 25 made of aluminum. Reference numeral 26 denotes a bolt for fixing the reinforcing plate 25 and the tube sheets 23, 23, 23. In this case, the vibration resistance is improved by the frame shape of the reinforcing plates 25, the tube sheets 23, 23, 23 and the reinforcing tube sheets 25, 25. Moreover, since the reinforcing plates 25, 25 have a flat plate shape, the resistance of the air blown out from the evaporator 7 does not increase.

The fin pitch Pf ₁ in the evaporator 7
Is set to 3 mm, for example, and the fin pitch Pf ₂ of the reheat heat exchanger 17 is set to 5 mm, for example. That is, Pf ₁ >
It is Pf ₂ . In this way, the ventilation resistance of the air passing through the reheat heat exchanger 17 can be made smaller than the ventilation resistance in the evaporator 7, and the increase in the ventilation resistance due to the addition of the reheat heat exchanger 17 can be suppressed. be able to.

The reheat heat exchanger 17 has a length equal to that of the evaporator 7, a width approximately one third of the evaporator 7, and a heat transfer tube 1.
It has a thickness dimension arranged in a row, and is attached to the center of the evaporator 7 in the width direction.

The reheat heat exchanger 17 has a tube sheet 23,
23, 23 are attached to the evaporator 7 by fixing them to the tube sheets 20, 20, 20 of the evaporator 7 with bolts 27, 27, 27. Reference numeral 28 denotes a mounting piece provided on each tube sheet 23. In this case, a special mounting member is not required for mounting the reheat heat exchanger 17, and the mounting structure can be simplified.

The refrigerant inlet 29 of the reheat heat exchanger 17 and the flow divider 11 serving as the refrigerant inlet to the evaporator 7 are located at the same position. In this case, the temperature distribution in the evaporator 7 and the temperature distribution in the reheat heat exchanger 17 are oppositely opposed. That is, the refrigerant inlet side of the evaporator 7 (ie,
The low-temperature region Z, which is the flow divider 11 side), the high-temperature region X ', which is the refrigerant inlet 29 side of the reheat heat exchanger 17, and the high-temperature region X, which is the anti-refrigerant inlet side of the evaporator 7, High temperature region Z 'on the side opposite to the refrigerant inlet and intermediate temperature region Y of evaporator 7
And the intermediate temperature region Y 'of the reheat heat exchanger 17 are opposed to each other, and the temperature distribution of the blown air W (see FIG. 4) blown through the evaporator 7 and the reheat heat exchanger 17 is made uniform. Can be changed.

As shown in FIG. 7, the refrigeration unit 2 having the above-described structure includes a compressor 4, a condenser 5, a receiver 30, an electromagnetic on-off valve 31, a valve closed when operation is stopped, an electronic expansion valve 32, and the evaporator 7, as shown in FIG. A supercooling heat exchanger for providing supercooling to the liquid refrigerant by exchanging heat between the liquid refrigerant guided from the receiver 30 and the gas refrigerant guided from the evaporator 7, comprising a refrigerant circuit A connected in order. 33 is provided.

The refrigerant circuit A is provided with a liquid injection circuit 34 for injecting a part of the liquid refrigerant guided from the receiver 30 into the suction side of the compressor 4. Reference numeral 35 denotes an electromagnetic on-off valve that is opened at the time of liquid injection, and reference numeral 36 denotes a capillary tube for reducing the pressure of the injection liquid.

In the refrigerant circuit A, the compressor 4
A part of the refrigerant discharged from the refrigerant (that is, hot gas) is bypassed to the condenser 4, the receiver 30, the solenoid on-off valve 31, and the electronic expansion valve 32, and the reheat heat exchanger 17 and the drain pan heater 37. A bypass circuit 38 leading to the inlet side of the evaporator 7 through the
And a proportional valve 39 for proportionally distributing the discharged gas refrigerant (that is, hot gas) to the condenser 5 side, and supplying the discharged gas refrigerant (that is, hot gas) to the reheat heat exchanger 17 and the drain pan heater 37. A three-way valve 40 is provided for supplying the gas to the inlet side of the evaporator 7.

In the refrigeration container configured as described above,
When storing items (for example, bulbs) that need to be stored at low humidity, a chilled mode operation is performed in which the amount of hot gas bypass by the proportional valve 39 is controlled. The blown air W that has been cooled and dehumidified by the evaporator 7 is reheated by the discharged gas refrigerant (that is, hot gas) supplied to the reheat heat exchanger 17 to reduce the relative humidity, and the container body 1 It will be supplied inside. Therefore, the inside of the container body 1 has a low humidity, which provides an optimum environment for storing bulbs. Moreover, the reheat heat exchanger 17 to which the discharged gas refrigerant (that is, hot gas) is supplied is configured separately from the evaporator 7 and is attached to the leeward side of the evaporator 7. In addition, no extra throttle mechanism is required, the mounting structure is simplified, and a low-cost and efficient reheating function can be exhibited.

In the refrigeration container having the above-described structure, moisture contained in the air is frosted on the evaporator 7 during the cooling operation. When the frost formation reaches a limit, a defrosting operation for melting and removing the frost formation is executed since the cooling capacity is greatly reduced. In the defrosting operation, the proportional valve 39 is connected to the bypass circuit 3.
Control so that 100% of the discharge gas refrigerant (that is, hot gas) flows to the 8 side, and switch the three-way valve 40 so that the discharge gas refrigerant (that is, hot gas) flows to the reheat heat exchanger 17 side. Thus, the discharge gas refrigerant (ie,
The entire amount of hot gas) passes through the bypass circuit 38 and evaporator 7
It is performed as it is supplied to.

During the defrosting operation, the discharge gas refrigerant (ie, hot gas) is supplied to the evaporator 7 through the reheat heat exchanger 17, and the frost on the lower surface side of the evaporator 7 is reduced. The molten gas is heated and melted by the discharged gas refrigerant (that is, hot gas) supplied to the evaporator 7, and heat is transferred from the reheat heat exchanger 17 to which the discharged gas refrigerant (that is, hot gas) is supplied. Will also be heated and melted. Therefore, the frost on the lower surface side of the evaporator 7, which has conventionally been difficult to completely melt, can be completely melted, and the defrosting efficiency can be greatly improved.
Moreover, the discharged gas refrigerant (that is, the discharged gas refrigerant) is supplied to the drain pan heater 37.
An existing circuit for supplying hot gas) can be used to supply the discharge gas refrigerant (that is, hot gas) to the reheat heat exchanger 17 during the defrosting operation, which complicates the circuit configuration. The defrosting efficiency can be improved without causing the defrosting.

[0035]

According to the present invention, a container body 1 for storing articles to be stored and a compressor 4 and a fan 6 outside the refrigerator are arranged on the front side of the container body 1 to cool the inside of the container body 1. In a refrigerating container provided with a condensing unit 5 and a refrigerating unit 2 provided with an evaporator 7 provided with an in-compartment fan 8, a gaseous refrigerant discharged from the compressor 4 (ie, A reheat heat exchanger 17 to which hot gas is supplied by-passing the condenser 5 is provided in contact with the lower surface of the evaporator 7 and the reheat heat exchanger 17 passes through the reheat heat exchanger 17 during the defrosting operation. Since the discharge gas refrigerant (that is, hot gas) is supplied to the evaporator 7, the frost on the lower surface side of the evaporator 7 causes the discharge gas refrigerant (that is, hot gas) to be supplied to the evaporator 7. Is heated and melted by Heat frost is also caused by heat conduction from the reheat heat exchanger 17 to which the refrigerant (that is, hot gas) is supplied, and frost formation on the lower surface side of the evaporator 7 which has conventionally been difficult to completely melt. Can be completely melted, and the defrosting efficiency can be greatly improved.

As described in the second aspect of the present invention, the reheat heat exchanger 17 is connected to the proportional valve 13 from the inlet side of the condenser 2.
In the bypass circuit 38 which branches through the drain pan heater 37 and reaches the inlet side of the evaporator 7, the bypass circuit 38 is provided upstream of the drain pan heater 37, and the bypass circuit 38 is provided with a dehumidifying operation and a defrosting operation. During operation, the discharge gas refrigerant (that is, hot gas) is supplied to the reheat heat exchanger 17, and during other operations, the reheat heat exchanger 17 and the drain pan heater 37 are bypassed to evaporate. When a three-way valve 40 that switches the refrigerant flow direction so as to supply the refrigerant to the inlet side of the heater 7 is provided,
Supplying the discharged gas refrigerant (that is, hot gas) to the reheat heat exchanger 17 during the defrosting operation using an existing circuit for supplying the discharged gas refrigerant (that is, hot gas) to the refrigerant 7 Thus, the defrosting efficiency can be improved without complicating the circuit configuration.

[Brief description of the drawings]

FIG. 1 is a front view of a refrigeration container according to an embodiment of the present invention.

FIG. 2 is a rear view showing a part of the refrigeration container according to the embodiment of the present invention in cross section.

FIG. 3 is a side view of the refrigeration unit in the refrigeration container according to the embodiment of the present invention.

FIG. 4 is an enlarged front view of an evaporator portion in the refrigeration container according to the embodiment of the present invention.

FIG. 5 is an enlarged side view showing an attached state of an evaporator and a reheat heat exchanger in the refrigeration container according to the embodiment of the present invention.

FIG. 6 is an enlarged bottom view showing an attached state of an evaporator and a reheat heat exchanger in the refrigeration container according to the embodiment of the present invention.

FIG. 7 is a refrigerant circuit diagram of a refrigeration unit in the refrigeration container according to the embodiment of the present invention.

[Explanation of symbols]

1 is a container body, 2 is a refrigeration unit, 4 is a compressor, 5
Is a condenser, 6 is an external fan, 7 is an evaporator, 8 is an internal fan, 11 is a diverter, 17 is a reheat heat exchanger, 37 is a drain pan heater, 38 is a bypass circuit, 39 is a proportional valve, 40
Is a three-way valve.

Claims (2)

[Claims] 1. A container body (1) for storing stored items.
And a condenser (5) and a fan inside the container, which are disposed on the front side of the container body (1) to cool the inside of the container body (1), and are provided with a compressor (4) and an external fan (6). (8)
Refrigeration unit (2) equipped with an evaporator (7) provided with
A reheat heat in which the gas refrigerant discharged from the compressor (4) is supplied to the leeward side of the evaporator (7) through the condenser (5). Exchanger (17)
Is attached in contact with the lower surface of the evaporator (7),
A refrigerating container, wherein a discharge gas refrigerant is supplied to the evaporator (7) via the reheat heat exchanger (17) during a defrosting operation. 2. The reheat heat exchanger (17) branches off from the inlet side of the condenser (2) via a proportional valve (13),
In a bypass circuit (38) extending to the inlet side of the evaporator (7) through the drain pan heater (37), the bypass circuit (38) is provided upstream of the drain pan heater (37), and the bypass circuit (38) has dehumidification. During the operation and the defrosting operation, the discharged gas refrigerant is supplied to the reheat heat exchanger (17).
During the other operation, the refrigerant flow direction is switched so that the reheat heat exchanger (17) and the drain pan heater (37) are bypassed and supplied to the inlet side of the evaporator (7). The refrigeration apparatus for a refrigeration container according to claim 1, wherein a three-way valve (40) is interposed.