JP2005009779A - Drain water evaporator for cooling device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drain water evaporator for a cooling device, capable of efficiently evaporating drain water by effectively using waste heat from a compressor and a condenser. <P>SOLUTION: In this drain water evaporator for the cooling device R, the cooling device R comprises the compressor 17, the condenser 18, a cooler 12, and a blower for the condenser for ventilating the condenser 18 and the compressor 17 for air cooling. The evaporator comprises a first evaporating dish 23 arranged above the compressor 17 for receiving drain water from the cooler 12, and a second evaporating dish 24 arranged below the condenser 18 for receiving drain water from the first evaporating dish 23. The first and second evaporating dishes 23, 24 are ventilated by the blower for the condenser. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a drain water evaporator of a cooling device used in a refrigeration air conditioner, for example, a refrigerator, a refrigerated showcase or an air conditioner.
[0002]
[Prior art]
Conventionally, a drain water evaporator of this type of cooling device has been provided with a metal evaporating dish in a machine room formed in the lower part of a main body of a refrigerator or the like, and drain water from the cooler is received by this evaporating dish. . And the drain water in an evaporating dish was forcedly heat-processed with the electric heater arrange | positioned in this evaporating dish.
[0003]
However, the treatment method by forced evaporation of drain water using an electric heater has a problem that the power consumption is large and the running cost increases. In particular, in a large showcase, a water level sensor is provided to detect the water level, thereby controlling the ON / OFF of the electric heater. However, the drain water discharged from the cooler of the large showcase is large. Usually, the electric current of the electric heater is often 100%. For this reason, power consumption is increased, energization time is prolonged, and improvement in energy saving has been desired.
[0004]
Therefore, conventionally, in order to solve the technical problem, a drain water evaporating apparatus of a cooling device is configured by an evaporating dish for receiving drain water and an evaporating member installed in the evaporating dish (see Patent Document 1). . This evaporating member is formed by bending a belt-like hydrophilic perforated plate in a meandering manner, and the drain water having a high temperature in the evaporating dish evaporates from the drain water surface and from the lower part of the evaporating member. It was sucked up and evaporated from the surface of the evaporation member.
[0005]
[Patent Document 1]
Japanese Patent No. 2698255
[0006]
[Problems to be solved by the invention]
However, the drain water evaporator of the conventional cooling device promotes the evaporation of the drain water by using the exhaust heat of the condenser by the ventilation of the condenser fan. Since it was not the structure utilized for evaporation of drain water, the evaporation promotion of drain water which used the exhaust heat exhausted from a machine room effectively was not aimed at.
[0007]
In addition, when a door is frequently opened and closed in a large showcase or the like, since the outside air containing a lot of humidity enters the showcase, more drain water is generated. However, there was a problem that the evaporation capacity was insufficient. Therefore, there has been a problem that maintenance work to reach the drain tray and drain the drain water that has not been evaporated to the outside must be frequently performed, and the management work becomes complicated.
[0008]
Therefore, the present invention has been made to solve the conventional technical problems, and cooling that enables efficient drain water evaporation processing by effectively using the exhaust heat from the compressor and the condenser. It aims at providing the drain water evaporation apparatus of an apparatus.
[0009]
[Means for Solving the Problems]
The drain water evaporator of the cooling device of the present invention is a cooling device comprising a compressor, a condenser, a cooler, and a condenser fan for ventilating the condenser and the compressor for air cooling. The first evaporating dish disposed above the condenser and receiving drain water from the cooler, and the second evaporating dish disposed below the condenser and receiving drain water overflowing from the first evaporating dish And the ventilation fan for the condenser is used to ventilate the first and second evaporating dishes. Therefore, when the compressor and the blower for the condenser are operated, the hot air including the exhaust heat from the condenser and the exhaust from the compressor are discharged. Heat can be effectively supplied to the first evaporating dish, and the evaporation of drain water received in the first evaporating dish can be promoted.
[0010]
Further, since the exhaust heat from the condenser can be supplied to the second evaporating dish by the condenser blower, the draining water received in the second evaporating dish cannot be completely evaporated in the first evaporating dish. Evaporation can be promoted.
[0011]
For this reason, even when a relatively large drain water evaporation treatment capacity is required, such as a cooling storage with a high frequency of opening and closing the door, it is possible to effectively drain the water by utilizing the exhaust heat from the condenser and the compressor. Water can be evaporated, and special maintenance work such as waste water treatment of surplus drain water can be reduced.
[0012]
According to a second aspect of the present invention, there is provided a drain water evaporation device for a cooling device according to the above invention, wherein the first evaporation dish is partitioned into a plurality of evaporation chambers, and each of the evaporation chambers overflows from the upstream evaporation chamber. Since the water sequentially flows into the evaporation chamber on the downstream side, the drain water whose temperature has been raised by heating with warm air including exhaust heat from the condenser and compressor is divided in stages. The drain water evaporation effect can be further improved.
[0013]
Particularly, since each of the evaporation chambers is partitioned by a plurality of partition walls having a notch formed at the upper end as in the invention of claim 3, the drain water that could not be completely evaporated in the upstream evaporation chamber is separated from the partition walls. It is possible to allow the drainage water to flow into the respective evaporation chambers without any special work, and to easily carry out the invention of claim 2. become able to.
[0014]
According to a fourth aspect of the present invention, there is provided the drain water evaporation device of the cooling device according to each of the above inventions, wherein the drain water from the cooler flows into the first evaporating dish and an inflow portion in which a U trap is formed is formed. Therefore, the cool air from the cooler can be sealed with the drain water stored in the inflow portion. Thereby, the temperature fall in a 1st evaporating dish can be suppressed and the improvement of the evaporation efficiency of drain water can be aimed at now.
[0015]
According to a fifth aspect of the present invention, there is provided the drain water evaporator of the cooling device according to the fifth aspect, wherein the first evaporating dish has an evaporating plate erected in a direction substantially along the ventilation from the condenser blower. Since the attachment portion is formed, the evaporation plate can be easily erected in the direction along the ventilation from the condenser blower. Thereby, even if it is a case where an evaporation plate is attached to an evaporation plate attaching part, the improvement of the evaporation efficiency of this evaporation plate can be aimed at, and evaporation of drain water can be accelerated | stimulated.
[0016]
According to a sixth aspect of the present invention, there is provided a drain water evaporator of the cooling device according to the above invention, wherein the compressor, the condenser, the blower for the condenser, and each evaporating dish are in a machine room configured below the heat insulating wall in which the cooler is installed. The first evaporating dish is inserted and held in an insertion hole formed in the bottom surface of the heat insulating wall that becomes the top surface of the machine room at the upper end on one side orthogonal to the ventilation from the condenser blower. And an engaging claw removably engaged with an engaging hole formed in the bottom surface of the heat insulating wall at the upper end of the other side, so that the first evaporating dish can be easily attached to the heat insulating wall. Detachable on the bottom. Thereby, even if dust or the like is accumulated on the first evaporating dish, it can be easily removed and cleaned, and convenience is improved.
[0017]
The drain water evaporator of the cooling device of the invention of claim 7 is the cooling device according to each of the above inventions, since the first evaporating dish is provided with protruding pieces protruding downward on both sides orthogonal to the ventilation from the condenser blower. Even when the apparatus is swung, the drain water on the first evaporating dish overflows to the outside, and the inconvenience on the compressor, particularly the electrical terminal portion, can be suppressed.
[0018]
Further, since the upper part of the compressor is surrounded by the protruding piece of the first evaporating dish, the exhaust heat of the compressor can be effectively transmitted to the first evaporating dish. Thereby, the evaporation efficiency of the first evaporating dish can be further improved.
[0019]
According to the eighth aspect of the present invention, in the above-described invention, the drain water evaporator is provided with a spill prevention portion protruding inward at the upper edge of the first evaporating dish. Even when it is swung, the spill prevention part can suppress the inconvenience that the drain water in the first evaporating dish overflows to the outside. Therefore, even when the first evaporating dish is detached from the bottom surface of the heat insulating wall in the invention of claim 6, it is possible to prevent the drain water in the first evaporating dish from spilling to the outside. It will be possible to improve.
[0020]
The drain water evaporator of the cooling device according to the ninth aspect of the present invention is the above-described invention, wherein the second evaporating dish is arranged to protrude outward from the outer surface of the condenser. The amount of drain water in the second evaporating dish can be ascertained from the outside without being drawn out.
[0021]
According to a tenth aspect of the present invention, there is provided a drain water evaporation device according to each of the above inventions, wherein a barrier having a notch is provided at a position inside the outer surface of the condenser in the second evaporating dish. The so-called short cycle in which the air blown from the blower for equipment passes between the lower surface of the condenser and the upper surface of the second evaporating dish and is discharged to the outside can be suppressed. Moreover, since the notch is formed in the barrier, when a predetermined amount or more of drain water is stored in the second evaporating dish, the drain water can overflow to the outside of the barrier through the notch. It becomes like this.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view of a four-sided glass type refrigerated showcase 2 as an embodiment to which an evaporator of the cooling device R of the present invention is applied, FIG. 2 is a lower longitudinal sectional view of the refrigerated showcase 2, and FIG. FIG. 4 is a rear perspective view of the cooling unit portion 3 of the cooling device R, and FIG. 5 is a plan view of the cooling unit portion 3 of the cooling device R.
[0023]
In the refrigerated showcase 2 of the present embodiment, a storage chamber 8 having four sides surrounded by a glass door 6 and a double glass 7 at the top, a cooling chamber 9 below it and a machine chamber 11 at the bottom are formed. . A plurality of shelves (not shown) for displaying products are installed in the storage chamber 8, and a cooler 12 of the cooling device R and a blower for cooler (not shown) are arranged in the cooling chamber 9. .
[0024]
The cooling chamber 9 is defined in a container-like heat insulating wall 4 whose upper surface is opened, and a bottom frame 15 attached to an opening edge of the heat insulating wall 4 is attached with a lower end of the double glass 7. Yes. A cold air inlet (not shown) is formed in the bottom frame 15 inside one side edge of the heat insulating wall 4, and a cold air outlet (not shown) is formed inside the other side edge, and extends between the cold air inlet and the cold air outlet. A bottom plate (not shown) is erected, and the storage chamber 8 and the cooling chamber 9 are partitioned by the bottom plate. When the air blower for the cooler is operated, the cold air cooled by the cooler 12 is blown into the storage chamber 8 from the cold air outlet, and the cold air after circulating in the storage chamber 8 enters the cooling chamber 9 from the cold air inlet. A returning cold air circulation is compulsorily formed, whereby the inside of the storage chamber 8 is cooled to a predetermined refrigeration temperature.
[0025]
On the other hand, the machine room 11 is provided with side panels 37 and 37 each having a ventilation port 36 formed on the left and right side surfaces, and a front panel 40 having a suction port 38 formed on the front surface so as to be freely opened and closed. And in this machine room 11, the cooling unit part 3 is accommodated in the bottom face 4A lower side of the heat insulation wall 4. FIG. The cooling unit 3 includes, for example, a compressor 17, a condenser 18, a compressor 17, and a condenser 18 that form a cooling device R together with the cooler 12 on a base 16 having casters 22 attached to four corners of the lower surface. The condenser fan case 19 surrounded by the condenser fan case 19 and the condenser fan 21 (not shown) and the electrical box 21 are arranged.
[0026]
In the present embodiment, the condenser 18 is positioned on the base 16 on one front side, and a condenser fan case 19 having a condenser blower is disposed on the rear side. Further, a second evaporating dish 24 constituting a part of the drain water evaporator of the present invention is accommodated in a lower part of the condenser 18, that is, between the condenser 18 and the base 16 so as to be drawn forward. Yes. A compressor 17 is installed on the base 16 behind the condenser fan case 19, and an electrical box 21 is disposed in front of the base 16 located next to the condenser 18. . Thus, when the condenser blower is operated, outside air is sucked into the machine room 11 through the suction port 38 formed in the front panel 40, and the rear upper part of the machine room 11 through the condenser 18, that is, the compressor. 17 Blows out from above the machine room 11.
[0027]
In addition, the first evaporating dish constituting the drain water evaporating apparatus of the present invention, together with the second evaporating dish 24, above the compressor 17, that is, between the bottom surface 4 </ b> A of the heat insulating wall 4 and the compressor 17. 23 is arranged.
[0028]
Here, the first evaporating dish 23 will be described in detail. The first evaporating dish 23 is a dish-like member that opens to the upper surface and has a predetermined depth, and projecting pieces 28 that project downward are formed on both side ends and the rear end except for the front end. The evaporating dish 23 is partitioned into three evaporating chambers, a first evaporating chamber 32, a second evaporating chamber 33, and a third evaporating chamber 34 by partition walls 30 and 31.
[0029]
The partition wall 30 is located below the drain pipe 41 that guides the drain water from the cooler 12, that is, the drain water from the cooler 12 to the evaporating dish 23, and is higher than, for example, the depth dimension of the evaporating dish 23. It is formed by covering the peripheral side surface with a partition plate. One side of the partition wall 30 (in this embodiment, the inner side of the evaporating dish 23) is formed lower than the opposite side, and in this embodiment, it is formed in the partition wall 30 at the upper end of one side. A notch 30 </ b> A is formed for allowing drain water flowing into the evaporation chamber 32 to flow over a predetermined amount to the second evaporation chamber 33.
[0030]
Here, the drain pipe 41 is formed with an inflow portion in which a U trap is formed, and the drain water is stored in the evaporation chamber 32 through the drain pipe 41, so that the cooling chamber flows in with the drain water. The cold air from 9 is sealed with water.
[0031]
On the other hand, the partition wall 31 is provided over the front and rear so as to divide the inside of the first evaporating dish 23 into left and right, and in this embodiment, the side where the first evaporating chamber 32 is provided, that is, toward the side. The left side is a second evaporation chamber 33 and the right side is a third evaporation chamber 34. Further, the partition wall 31 flows into the second evaporation chamber 33 formed by the partition wall 31 at a predetermined amount or more at a position separated from the first evaporation chamber 32, that is, at the upper end of the rear portion of the partition wall 31. A cutout 31 </ b> A for overflowing the drained water overflowing into the third evaporation chamber 34 is formed. The notch 31A is formed so that the height of the upper end is lower than the upper end of the notch 30A formed in the partition wall 30.
[0032]
On the other hand, a drain water discharge portion 42 communicating with the evaporation chamber 34 is formed at the front end of the first evaporation dish 23 constituting the third evaporation chamber 34, and at the lower end of the drain water discharge portion 42. A drain hose 26 whose lower end opens above the second evaporating dish 24 is connected. Further, at the front end of the first evaporating dish 23 facing the drain water discharge portion 42, drain water that has flowed into the third evaporating chamber 34 by a predetermined amount or more into the second evaporating dish 24 through the drain hose 26. A cutout 23A for overflowing is formed. The notch 23A is formed so that the height of the upper end is lower than the upper end of the notch 31A formed in the partition wall 31.
[0033]
Further, in each of the second and third evaporation chambers 33 and 34, an evaporating plate (not shown) is provided in a direction substantially along the ventilation from the condenser blower 19, that is, in the present embodiment, in front and rear. A plurality of the evaporation plate attachment portions 43 are formed.
[0034]
On the other hand, at the upper end of the side surface of the first evaporating dish 23, that is, at the upper end of the left side surface in the present embodiment, insertion claws 45, 45 extending in the front and rear and extending substantially horizontally outward are formed. The insertion claws 45, 45 can be inserted into and removed from two insertion holes (not shown) formed in advance on the bottom surface 4 </ b> A of the heat insulating wall 4 corresponding to the top surface of the machine room 11. Further, on the side facing the insertion claws 45, 45, that is, on the upper end of the right side, there are formed engaging claws 46, 46 that are bent forward and backward and urged upwards. Similarly, the engaging claws 46 can be engaged with and disengaged from two engaging holes (not shown) formed in advance on the bottom surface 4A of the heat insulating wall 4.
[0035]
Thus, the first evaporating dish 23 can be easily attached to and detached from the bottom surface 4A of the heat insulating wall 4 by the insertion claws 45 and the engaging claws 46 formed at the upper ends on both sides orthogonal to the ventilation from the condenser blower 19. it can. Therefore, even if dust or the like is accumulated on the first evaporating dish 23, it can be easily removed and cleaned, and convenience is improved.
[0036]
3 to 5, reference numeral 47 denotes a fixed claw formed substantially horizontally at the upper end between the engaging claws 46, 46. The fixing claw 47 is formed with a screw hole 47A for fixing the first evaporating dish 23 to the bottom surface 4A of the heat insulating wall 4 with a decorative screw (not shown), thereby more stably. The first evaporating dish 23 can be fixed to the bottom surface 4A.
[0037]
Next, the second evaporating dish 24 will be described in detail. The second evaporating dish 24 is a dish-like member that opens to the upper surface and has a predetermined depth. A handle portion 24A that extends substantially horizontally forward is formed at the upper end of the front surface. Further, the evaporating dish 24 is positioned between the condenser 18 and the base 16 as described above, and is accommodated so as to be pulled out by moving the handle portion 24A forward or backward.
[0038]
Here, as shown in FIG. 5, the evaporating dish 24 is a position where the front end of the evaporating dish 24 protrudes forward from the front surface of the condenser 18 by a predetermined dimension, and the rear part of the evaporating dish 24 is the drain hose 26. It shall be arrange | positioned under the condenser 18 so that it may correspond to lower end opening of this. In order to always be able to store in this state, the rearward movement of the evaporating dish 24 is restricted on the base 16 at a position facing the rear surface of the evaporating dish 24 in the state in which the evaporating dish 24 is accommodated. It is assumed that a regulating member 50 is formed.
[0039]
As a result, when the evaporating dish 24 is once pulled forward and stored in the original state, the front end of the evaporating dish 24 can reliably protrude forward by a predetermined dimension from the front surface of the condenser 18 and evaporate. It can arrange | position so that the drain water from the drain hose 26 may be received in the rear part of the dish 24.
[0040]
Further, in the evaporating dish 24, a barrier 48 having a notch 48 </ b> A formed at the upper end is erected by reinforcing members 49, 49, located on the inner side of the front surface of the condenser 18.
[0041]
With the above configuration, the drain water treatment process of the drain water evaporator of the present invention will be described. By operating the cooling device R, the drain water dripped from the cooler 12 is received in the first evaporation chamber 32 of the first evaporating dish 23 via the drain pipe 41. Here, since the compressor 17 and the condenser blower in the machine room 11 are in operation, the outside air flowing into the machine room 11 from the suction port 38 of the front panel 40 is heated by the operation of the cooling device R. It becomes warm air through the condenser 18 and is blown out behind the machine room 11. Therefore, the drain water received in the evaporating dish 23 is heated by the warm air including the exhaust heat from the condenser 18 to rise in temperature, and is evaporated. Moreover, since the said evaporating dish 23 is arrange | positioned above the compressor 17, the waste heat of the compressor 17 is utilized for the evaporation process of drain water.
[0042]
Accordingly, the drain water received in the first evaporating dish 23 is effectively supplied to the first evaporating dish 23 by supplying the warm air including the exhaust heat from the condenser 18 and the exhaust heat from the compressor 17 to the first evaporating dish 23. It becomes possible to promote the evaporation of.
[0043]
However, when drain water having a capacity equal to or greater than the evaporation capacity of the first evaporation chamber 32 of the evaporation dish 23 flows into the first evaporation chamber 32, the height of the cutout 30A formed in the partition wall 30 is larger. As the water level rises, drain water overflows into the second evaporation chamber 33.
[0044]
The drain water received in the second evaporation chamber 33 is heated by the warm air including the exhaust heat of the condenser 18 and the exhaust heat from the compressor 17 in the same manner as the drain water received in the first evaporation chamber 32. The temperature rises and the evaporation process is performed.
[0045]
However, when an amount of drain water that cannot be covered by the evaporation capacity of the second evaporation chamber 33 of the evaporation dish 23 flows into the second evaporation chamber 33, the notch 31A formed in the partition wall 31 As the water level rises above the height, drain water overflows into the third evaporation chamber 34.
[0046]
The drain water received in the third evaporation chamber 34 is heated by the warm air including the exhaust heat of the condenser 18 and the exhaust heat from the compressor 17 in the same manner as the drain water received in the first evaporation chamber 32. The temperature rises and the evaporation process is performed.
[0047]
As a result, the drain water overflowing from the upstream evaporation chamber 32 sequentially flows into the downstream evaporation chambers 33 and 34, so that the hot water including the exhaust heat from the condenser 18 and the compressor 17 is used. By separating the drain water whose temperature has been increased by heating in stages, the evaporation effect of the drain water can be further improved.
[0048]
In particular, since each of the evaporation chambers 32, 33, 34 is partitioned by the partition walls 30, 31 having notches 30A, 31A formed at the upper end, the drain that could not be evaporated in the upstream evaporation chambers 32, 33 could be drained. Water can overflow into the evaporation chamber 34 on the downstream side of the notches 30A and 31A of the partition walls 30 and 31, and drain water flows into the evaporation chambers 33 and 34 without performing any special work. Therefore, the stepwise separation of drain water can be easily performed.
[0049]
In the present embodiment, since the first evaporating dish 23 has projecting pieces 28 projecting downward on both sides and the rear side perpendicular to the ventilation from the condenser blower, the cooling device R swings. Even in such a case, the drain water in the first evaporating dish 23 overflows to the outside, and it is possible to suppress inconvenience on the compressor 17, particularly the electrical equipment terminal portion.
[0050]
Further, since the upper portion of the compressor 17 is surrounded by the protruding piece 28 of the first evaporating dish 23, the exhaust heat of the compressor 17 can be effectively transmitted to the first evaporating dish 23. Thereby, the evaporation efficiency of the first evaporating dish 23 can be further improved.
[0051]
In the present embodiment, since the protruding piece 28 is not formed on the front side of the first evaporating dish 23, it is possible to supply the wind from the front of the machine chamber 11 to the compressor 17, and the compressor 17 itself is excessively excessive. Heating can be prevented.
[0052]
Further, in the present embodiment, as described above, the drain pipe 41 for allowing the drain water from the cooler 12 to flow into the first evaporation chamber 32 is formed with an inflow portion in which a U trap is formed. Can be sealed with drain water stored in the inflow part or the evaporation chamber 32, the temperature drop in the first evaporating dish 23 can be suppressed, and the evaporation efficiency of drain water can be improved. It becomes possible to plan.
[0053]
In order to further improve the evaporating efficiency of the first evaporating dish 23, for example, an evaporating plate made of a hydrophilic porous plate may be erected on each evaporating plate mounting portion 43, 43, for example. And Here, since the evaporation plate is erected in a direction substantially along the ventilation from the condenser fan, the evaporation efficiency of the evaporation plate can be further improved, and the evaporation of drain water can be promoted. it can.
[0054]
For example, a relatively large drain water evaporation processing capability such as a cooling storage with a high door opening / closing frequency is required, and the evaporation processing capability may be insufficient with only the first evaporating dish 23. In such a case, the water level rises above the height of the notch 24A formed at the front end of the first evaporating dish 23, so that the drain water in the third evaporating chamber 34 is drained from the drain water discharge section 42 and It overflows to the second evaporating dish 24 through the drain hose 26.
[0055]
The drain water received in the second evaporating dish 24 is heated by the warm air including the exhaust heat of the condenser 18 flowing around the lower side of the condenser 18, the temperature rises, and is evaporated. As a result, the evaporation process cannot be completed in the first evaporating dish 23, and the evaporation of drain water received in the second evaporating dish 24 can be promoted.
[0056]
Therefore, even when a relatively large drain water evaporation processing capacity is required, such as a cooling storage with a high frequency of opening and closing the door, it is effective by utilizing the exhaust heat from the condenser 18 and the compressor 17. In addition, it is possible to evaporate the drain water, and it is possible to reduce extraordinary maintenance work such as drainage treatment of excess drain water.
[0057]
Further, in the present invention, since the barrier 48 having the notch 48A is erected at a position inside the outer surface of the condenser 18 in the second evaporating dish 24, the blast from the condenser blower is sent to the condenser 18. It is possible to suppress a so-called short cycle that passes between the lower surface and the upper surface of the second evaporating dish 24 and is discharged forward. Furthermore, since the notch 48A is formed in the barrier 48, when a predetermined amount or more of drain water is stored in the second evaporating dish 24, the drain water flows from the upper end of the notch 48A to the front side of the barrier 48. Overflowing can be notified to the user that excessive drain water is stored in the second evaporating dish 24.
[0058]
In particular, since the front end of the second evaporating dish 24 protrudes forward from the front surface of the condenser 18 as described in detail above, the second evaporating dish 24 can be drawn from the front without pulling the second evaporating dish 24 forward. The amount of drain water in the second evaporating dish 24 can be grasped.
[0059]
Further, the second evaporating dish 24 is disposed below the condenser 18 and can be easily pulled out from the front. Therefore, excessive drainage is generated in the second evaporating dish 24 due to generation of abnormal drain water. Even if the water is stored, the drainage operation can be easily performed.
[0060]
In this embodiment, when the evaporation plate is not attached, a spill prevention portion (not shown) protruding inward may be provided on the upper edge portion of the first evaporation tray 23. Thereby, even if it is a case where the cooling device R is shaken, the inconvenience that the drain water in the 1st evaporating dish 23 overflows outside by a spill prevention part can be suppressed now. Therefore, even when the first evaporating dish 23 is detached from the bottom surface 4A of the heat insulating wall 4, the drain water in the first evaporating dish 23 can be prevented from spilling outside, and the convenience is improved. Can be planned.
[0061]
【The invention's effect】
As described above in detail, according to the present invention, in a cooling device including a compressor, a condenser, a cooler, and a condenser blower for air cooling through the condenser and the compressor, A first evaporating dish disposed above and receiving drain water from the cooler; and a second evaporating dish disposed below the condenser and receiving drain water overflowing from the first evaporating dish; Since the first and second evaporating dishes are ventilated by the condenser blower, the warm air including the exhaust heat from the condenser and the exhaust heat from the compressor are operated by operating the compressor and the condenser blower. Can be effectively supplied to the first evaporating dish, and the evaporation of drain water received in the first evaporating dish can be promoted.
[0062]
Further, since the exhaust heat from the condenser can be supplied to the second evaporating dish by the condenser blower, the draining water received in the second evaporating dish cannot be completely evaporated in the first evaporating dish. Evaporation can be promoted.
[0063]
For this reason, even when a relatively large drain water evaporation treatment capacity is required, such as a cooling storage with a high frequency of opening and closing the door, it is possible to effectively drain the water by utilizing the exhaust heat from the condenser and the compressor. Water can be evaporated, and special maintenance work such as waste water treatment of surplus drain water can be reduced.
[0064]
According to the invention of claim 2, in the above invention, the inside of the first evaporating dish is divided into a plurality of evaporating chambers, and each evaporating chamber has drain water that has overflowed from the upstream evaporating chamber in order on the downstream side. Since it is configured to flow into the evaporation chamber, the drain water is further evaporated by dividing the drain water whose temperature has been increased by heating with warm air including exhaust heat from the condenser and compressor, in stages. The effect can be improved.
[0065]
Particularly, since each of the evaporation chambers is partitioned by a plurality of partition walls having a notch formed at the upper end as in the invention of claim 3, the drain water that could not be completely evaporated in the upstream evaporation chamber is separated from the partition walls. It is possible to allow the drainage water to flow into the respective evaporation chambers without any special work, and to easily carry out the invention of claim 2. become able to.
[0066]
According to the invention of claim 4, in each of the above inventions, drain water from the cooler flows into the first evaporating dish and an inflow portion in which a U trap is formed is formed. The cool air from the vessel can be sealed with drain water stored in the inflow portion. Thereby, the temperature fall in a 1st evaporating dish can be suppressed and the improvement of the evaporation efficiency of drain water can be aimed at now.
[0067]
According to the invention of claim 5, in each of the above inventions, the first evaporating dish is provided with an evaporating plate mounting portion for erecting the evaporating plate in a direction substantially along the ventilation from the condenser blower. Therefore, the evaporating plate can be easily erected in the direction along the ventilation from the condenser blower. Thereby, even if it is a case where an evaporation plate is attached to an evaporation plate attaching part, the improvement of the evaporation efficiency of this evaporation plate can be aimed at, and evaporation of drain water can be accelerated | stimulated.
[0068]
According to the invention of claim 6, in each of the above inventions, the compressor, the condenser, the condenser fan, and each evaporating dish are installed in a machine room formed below a heat insulating wall in which a cooler is installed, The evaporating dish of 1 includes an insertion claw that is inserted and held in an insertion hole formed in a bottom surface of a heat insulating wall serving as a top surface of the machine room at an upper end on one side orthogonal to the ventilation from the condenser blower. Since the upper end of the other side is provided with an engaging claw removably engaged with an engaging hole formed in the bottom surface of the heat insulating wall, the first evaporating dish can be easily detached from the bottom surface of the heat insulating wall. become able to. Thereby, even if dust or the like is accumulated on the first evaporating dish, it can be easily removed and cleaned, and convenience is improved.
[0069]
According to the invention of claim 7, in each of the above inventions, the first evaporating dish is provided with projecting pieces projecting downward on both sides orthogonal to the ventilation from the condenser blower, so that the cooling device was swung. Even in this case, the drain water on the first evaporating dish overflows to the outside, and it is possible to suppress inconvenience on the compressor, in particular, the electrical terminal portion.
[0070]
Further, since the upper part of the compressor is surrounded by the protruding piece of the first evaporating dish, the exhaust heat of the compressor can be effectively transmitted to the first evaporating dish. Thereby, the evaporation efficiency of the first evaporating dish can be further improved.
[0071]
According to the invention of claim 8, in each of the above inventions, the upper edge portion of the first evaporating dish is provided with the spill prevention portion projecting inward, so that the cooling device is shaken. However, the inconvenience that the drain water in the first evaporating dish overflows to the outside by the spill prevention part can be suppressed. Therefore, even when the first evaporating dish is detached from the bottom surface of the heat insulating wall in the invention of claim 6, it is possible to prevent the drain water in the first evaporating dish from spilling to the outside. It will be possible to improve.
[0072]
According to the invention of claim 9, in each of the above inventions, the second evaporating dish is arranged to protrude outward from the outer surface of the condenser, so that the second evaporating dish is not drawn out, It becomes possible to grasp the amount of drain water in the second evaporating dish from the outside.
[0073]
According to the invention of claim 10, in each of the above-mentioned inventions, since a barrier having a notch is erected at a position inside the condenser outer surface in the second evaporating dish, air from the condenser blower is blown. Thus, it is possible to suppress a so-called short cycle that is discharged between the lower surface of the condenser and the upper surface of the second evaporating dish and discharged to the outside. Moreover, since the notch is formed in the barrier, when a predetermined amount or more of drain water is stored in the second evaporating dish, the drain water can overflow to the outside of the barrier through the notch. It becomes like this.
[Brief description of the drawings]
FIG. 1 is a perspective view of a four-sided glass type refrigerated showcase as an embodiment to which an evaporator of a cooling device of the present invention is applied.
FIG. 2 is a lower longitudinal sectional view of a refrigerated showcase.
FIG. 3 is a front perspective view of a cooling unit portion of the cooling device.
FIG. 4 is a rear perspective view of a cooling unit portion of the cooling device.
FIG. 5 is a plan view of a cooling unit portion of the cooling device.
[Explanation of symbols]
R Cooling device
2 Refrigerated showcase
3 Cooling unit
4 Insulation wall
4A Bottom
11 Machine room
17 Compressor
18 Condenser
23 First evaporating dish
23A, 30A, 31A, 48A Notch
24 Second evaporating dish
26 Drain hose
28 Protruding piece
30, 31 partition wall
32, 33, 34 Evaporation chamber
41 Drain piping
43 Evaporating plate attachment
45 Insertion claw
46 engaging claw
48 barriers

Claims (10)

In a cooling device comprising a compressor, a condenser, a cooler, and a condenser blower for air cooling by passing through the condenser and the compressor,
A first evaporating dish disposed above the compressor and receiving drain water from the cooler, and disposed below the condenser and receiving drain water overflowing from the first evaporating dish. And a second evaporating dish
A drain water evaporator for a cooling device, wherein the condenser blower ventilates the first and second evaporating dishes. The inside of the first evaporating dish is divided into a plurality of evaporating chambers, and each evaporating chamber is configured such that drain water overflowing from the upstream evaporating chamber sequentially flows into the downstream evaporating chamber. The drain water evaporator of the cooling device according to claim 1, wherein 3. The drain water evaporation device for a cooling device according to claim 2, wherein each of the evaporation chambers is partitioned by a plurality of partition walls having notches formed at the upper end. The drainage water from the cooler flows into the first evaporating dish, and an inflow portion in which a U trap is formed is formed. 3 is a drain water evaporator of the cooling device; The evaporating plate mounting portion for erecting an evaporating plate in a direction substantially along the ventilation from the condenser blower is formed in the first evaporating dish. The drain water evaporation device of the cooling device according to claim 2 or claim 3. The compressor, the condenser, the blower for the condenser and each evaporating dish are installed in a machine room configured below the heat insulating wall where the cooler is installed,
The first evaporating dish is inserted and held in an insertion hole formed in a bottom surface of the heat insulating wall serving as a top surface of the machine room at an upper end on one side orthogonal to the ventilation from the condenser blower. An insertion claw is provided, and an engagement claw detachably engaged with an engagement hole formed in the bottom surface of the heat insulating wall is provided at the upper end of the other side. 3. A drain water evaporation device for a cooling device according to claim 4, 4 or 5. The said 1st evaporating dish is provided with the protrusion piece which protrudes below on the both sides orthogonal to the ventilation from the said air blower for condensers, The claim 1, 2, 3, 4, The drain water evaporation apparatus of the cooling device of Claim 5 or Claim 6. The spill prevention part which protrudes inward is provided in the upper edge part of the said 1st evaporating dish, The claim | item 1, Claim 3, Claim 4, Claim 5 characterized by the above-mentioned. The drain water evaporator of the cooling device of Claim 6 or Claim 7. The said 2nd evaporating dish is protruded and arrange | positioned outward from the outer surface of the said condenser, The claim 1, The claim 3, The claim 4, The claim 5, The claim 6. A drain water evaporation device for a cooling device according to claim 7 or claim 8. The barrier which has a notch is standingly arranged in the position inside the said condenser outer surface in the said 2nd evaporating dish, The claim 2, The claim 3, The claim 4, The drain water evaporator of the cooling device of Claim 5, Claim 6, Claim 7, Claim 8 or Claim 9.

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