JPS63282470A - Cooling device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Object of the Invention] Industrial Application Field The present invention relates to a defrosting water treatment device in a cooling device.
More specifically, the present invention relates to a cooling device equipped with a processing device improved to better evaporate defrosting water.

In conventional cooling devices, frost forms on the cooler during its cooling operation, and depending on the degree of frost growth, the cooling capacity of the cooler is significantly reduced. For this reason, defrosting is usually performed using a heater, hot gas refrigerant circulation, or the like. The defrosting water generated by this defrosting is led to the machine room through a pipe or the like and stored in a drain tray. This drainage tray is arranged so that it can be freely spun, but depending on the usage conditions and installation environment, defrosting water may accumulate significantly, and the drainage tray must be frequently removed and the defrosting water must be disposed of. However, maintenance was a hassle. For this purpose, an evaporation pipe may be installed so as to be in contact with the bottom of the drain tray, or the defrost water may be immersed in the stored defrosting water. An example of this is disclosed in Japanese Utility Model Publication No. 58-54617.

Problems to be Solved by the Invention In the above-mentioned conventional technology, the high-pressure side pipe is immersed in the evaporation tray, and it is possible to evaporate the defrosting water stored in the evaporation tray by flowing high-temperature refrigerant. can. In addition, by providing a protrusion that protrudes at a predetermined height h2 approximately on the bottom of the evaporating dish, this protrusion comes into contact with the high-pressure side pipe when the evaporating dish is inserted into the fixed position, so that the evaporating dish is moved downward. This will prevent wobbling. However, the state in which this protrusion is in contact with the high-pressure side pipe is the normal state, and since high-temperature refrigerant flows through the high-pressure side pipe, the temperature of this pipe is inevitably high (approximately 80°C). It has become. Therefore, another limiting condition was added that the material of the evaporating dish must be selected so that it would not melt or deform at this temperature.

SUMMARY OF THE INVENTION Therefore, the present invention provides a cooling device equipped with an inexpensive defrost water treatment device that can be easily taken in and out of a machine room, can efficiently evaporate defrost water stored in an evaporation tray while stored. It is.

[Structure of the invention]

Means for Solving the Problems The cooling device of the present invention is formed by a heat insulating wall, and various mechanical parts are arranged below the main body for displaying and cooling stored items, and a cover with an air intake port is opened and closed in front of the main body. It is equipped with a machine room that can be freely installed, and a condenser that is located near the intake port and forms a space below it, a resin evaporation plate that can be moved in and out of the space, and an evaporator. The machine room is equipped with an evaporation pipe arranged to face into the dish, and a heat-resistant protection member interposed between the front inner surface of the evaporation dish and the evaporation pipe located in the front row.

An evaporation pipe (
A protective member (27) made of a heat-resistant material with a heat-resistant temperature of 80°C or higher is installed between the frontmost row of the evaporating plate (26), that is, the part located on the front side when loading and unloading, and the front inner surface of the evaporating dish (25). By interposing the evaporating dish (25) and the evaporating pipe (26)
) to avoid contact with the evaporating dish (25
) has a positioning function that defines the sliding range when storing.

EXAMPLES Examples of the present invention will be described below with reference to FIGS. 1 to 3.

(1) is a cooling device in which an opening (2) for storing and taking out products is formed on the front surface, and a transparent door (3) for freely opening and closing the opening (2) is pivotally attached to the front surface of the opening. This will be explained using a reach-in type refrigerated showcase as an example.

The cooling device (1) has an insulating wall (4) with a front opening (2)
The main body (5) is divided into a cooling chamber (7) and a storage chamber (8) by a partition plate (6).
It is divided into In addition, a machine room (9) is provided below the main body (5) to house electromechanical parts, which will be described later.
There is also an opening (10) in the front of this machine room (9) for storing and taking out mechanical parts, and this opening (10) serves as an intake port to form a plurality of air suction holes (11). It is closed by a cover (12) so that it can be opened and closed. The storage room (8) is partitioned vertically into a plurality of compartments (13) such as shelves, and products are placed on these shelves (13). In addition, the partition plate (6) is provided with an air outlet (
(not shown) and a suction port (14) are formed. The cooling chamber (7) includes an evaporator (1) that cools the air by circulating refrigerant.
5) is housed, and there is also a cooling room (7) and a machine room (9).
) is communicated with the drain pipe (16) provided by penetrating the heat insulating wall (4).

Next, to explain the machine room (9), there are seven condensers (21) from the front to the rear, and three condensers from the intake port (11) to the exhaust port (3).
A blower device (22) and a compressor (23) are arranged in this order to circulate air toward the air blower (22) and the compressor (23). The condenser (21) has its left and right ends fixed with tube plates (24), respectively. At this time, an evaporation plate (25) is disposed at the bottom of the condenser (21) so that it can be taken in and out, and an evaporation pipe is also installed. A space (B) is provided for arranging a high pressure side pipe (26). In addition, the distance between the bottom surface of the heat insulating wall (4) and the top surface of the tube plate (24) is set to a small distance of, for example, about 10 to 15 mm, so that the cover (12) can be placed close to this area.
The air sucked in from (11) flows into the
The upper surface area of the tube sheet (24) is made smaller than that of the condenser (21), thereby saving tube sheet material. Furthermore, the length in the air flow direction, that is, in the depth direction, at the top opening of the evaporating dish (25) is selected to be about 1.5 to 2.5 times the length in the depth direction of the condenser (21), and in this example, Set it to about 2 times. The high-pressure side pipe (26) facing into the evaporating dish (25) is preferably arranged over as wide a range as possible over the entire surface of the evaporating dish (25).

In addition, when loading and unloading the evaporating dish (25), the high pressure side pipe (
26) will not come into direct contact with the evaporating dish (25)5.
In addition, a protective member (27) made of a heat-resistant material with a heat-resistant temperature of 80°C or higher, such as natural rubber or neoprene rubber, is installed at a small distance (both at a certain distance from the front inner surface of the evaporating dish (25) on the pipe closest to you). Roll it up so that it remains intact.

It should be noted that this protective member (27) should not be specially provided (the tip of the connecting pipe (28) that connects to the drain pipe (16) and extends to the evaporating dish (25) should be connected to the high-pressure side pipe closest to you). (26), or may be positioned further forward than the nearest pipe, in short, the evaporation pipe (26) and the inner surface of the front side of the evaporation dish (25). It is sufficient to maintain a certain interval between them.

However, at least the tip of this connecting pipe (28) needs to be made of a material with a heat resistance temperature of 80° C. or higher.

On the other hand, when storing the evaporating dish (25),
) is preferably provided with a plate (29). Further, a filter (30) for collecting dust contained in the sucked air is detachably disposed in front of the condenser (21). (23) is a compressor that sends refrigerant to the refrigerant circuit and easily liquefies the refrigerant at room temperature.The refrigerant discharged from this compressor (23) is passed through the high pressure side pipe (26) to the condenser (21), undergoes heat exchange and reaches the evaporator (15) via an expansion valve (not shown), and then undergoes heat exchange and reaches the compressor (23) via a liquid receiver (not shown). Return.In addition, an exhaust port (31) is formed at the rear of the machine room (9) to discharge the sucked air.

In addition, when taking out the evaporating dish (25), first remove the filter (3) and remove it from the machine room (9).
The opening of the evaporating dish (25) to the front side is connected to the high pressure side pipe (2
6) until it touches the rearmost surface of the evaporating dish (2).
5) Tilt the front side upward so that the rear side of the opening is the high pressure side pipe (2).
6) Place the evaporating dish (25
) further and take it out from the machine room (9).

On the other hand, when inserting the evaporating dish (25), the procedure for removing it may be reversed.

According to the above configuration, air flows from the front side to the rear side of the machine room (9) as the blower (22) operates. (Surin) (11) The air sucked in from the filter (3
0) through the condenser (21) while being cooled.

Since the interval between the air passing through the upper part of the condenser (21) is small, the amount of air flowing out to the upper surface of the machine room (9) is very small. Therefore, there is no need to cover the top surface of the condenser (21) with the top surface of the tube plate (24).
Materials can be saved. In addition, by reducing the interval, some of the air passing through the lower part of the condenser (21)
) The air heated by heat exchange that flows into the upper opening of the evaporating tray (25) through the lower surface can participate in the evaporation of the defrosting water stored in the evaporating tray (25). Furthermore, an evaporating dish (2
By making the length in the depth direction of 5) approximately twice the length in the depth direction of the condenser (21), the amount of air flowing into the top opening of the evaporating dish (25) can be increased, so that high pressure A large amount of humid air generated by the side pipe (26) and the above-mentioned warmed air can be transported, and the evaporation capacity of the evaporation dish (25) can be improved.

On the other hand, the inner surface on the front side of the evaporating dish (25) is directly connected to the evaporating pipe (2
6), and the thermal influence of the evaporating pipe (26) does not affect the evaporating dish (25).
As for 5), it is possible to use a material with a low heat resistance temperature, for example, styrene resin with a temperature resistance of about 60° C., and it is possible to manufacture an inexpensive product by selecting the material. In addition, when installing the evaporating dish (25), the position where the evaporating dish (25) is slid until the front inner surface of the evaporating dish (25) comes into contact with the protective member (27) is the mounting position. Therefore, the protection member (27) can be used as a positioning member for the evaporation dish (25).

〔Effect of the invention〕

As detailed above, according to the present invention, the inner surface of the front side of the evaporating dish does not come into contact with the direct liquid evaporation pipe due to the interposition of the heat-resistant protective member, and the thermal influence of the evaporation pipe during cooling operation is reduced. Since the temperature is lower than that of an evaporating dish, it is possible to use a material with a low heat-resistant temperature for the evaporating dish, contributing to a reduction in material costs. Further, when storing the evaporating dish, the protective member can function as a positioning member that defines the sliding range of the evaporating dish, and the member can be used for multiple purposes.

[Brief explanation of the drawing]

Each figure shows one embodiment of the present invention, and FIG. 1 is A-A in FIG.
A sectional view, FIG. 2 is an external perspective view of the cooling device, and FIG. 3 is an enlarged view of the main part of FIG. 1. (1)...Cooling device, (4)...Insulating wall,
(5)...Main body, (7)...Cooling chamber, (8
)...Storage room, (9)...Machine room, (11)
...Slit, (12)...Cover, (21).
... Condenser, (25) ... Evaporation dish, (26)
...evaporation pipe, (27) ...protection member, (2
8)...Connecting pipe, (B)...Space.

Claims (1)

[Claims] 1. In a cooling device equipped with a machine room formed of a heat insulating wall and with various mechanical parts arranged below the main body for displaying and cooling stored items, and a cover with an air intake port provided in front thereof so as to be openable and closable, a condenser disposed near the intake port and forming a space below the inlet; a resin evaporation dish disposed so as to be freely put in and taken out of the space; and a condenser disposed facing into the evaporation dish. A cooling device characterized in that the machine room is provided with an evaporation pipe provided therein, and a heat-resistant protection member interposed between the front inner surface of the evaporation dish and the evaporation pipe located in the front row.