JP2019074308A - Open showcase - Google Patents

Abstract

To provide an open showcase which enables a drain pan for receiving drain water to be carry in/out to easily discharge the drain water in the drain pan and easily clean the drain pan.SOLUTION: An open showcase includes: a product exhibition room; a cooling part; a drain pan 35; a heating part; and a support mechanism 40. The cooling part includes a refrigeration cycle formed by connecting a compressor, a condenser, a pressure reducer, and an evaporator and cools air in the exhibition room. The drain pan receives drain water occurring in the evaporator. The heating part is housed in the drain pan and heats the drain water in the drain pan. The support mechanism supports the drain pan in a manner that the drain pan can be carried in/out without interfering with the heating part.SELECTED DRAWING: Figure 7

Description

  The embodiment of the present invention relates to an open showcase provided with a display room in which a plurality of shelves for placing products are stored and for cooling a product in the display room.

  2. Description of the Related Art An open showcase is known which is provided with a display room in which a plurality of shelves for placing products are stored, and which cools products in the display room. The open showcase includes a refrigeration cycle configured by connecting a compressor, a condenser, a pressure reducer, and an evaporator, and the air in the display chamber is circulated by circulating the air in the display chamber through the evaporator. Cooling.

  The moisture contained in the air in the display chamber condenses as it passes through the evaporator, becoming water droplets and adhering to the surface of the evaporator. The water droplets attached to the surface of the evaporator flow down from the evaporator as drain water, and partly freeze to form frost. This frost is melted by a defrosting operation that is performed periodically or as needed, and flows down from the evaporator as drain water.

  In Japanese Patent Application Laid-Open No. 2010-71572 which is a prior art, drain water flowing down from an evaporator is received by a first drain pan, and drain water flowing out of the first drain pan is received by a second drain pan. In the first drain pan, an outlet side refrigerant pipe of a condenser (dissipator) is disposed to improve the cooling efficiency. In the second drain pan, a discharge side refrigerant pipe of the compressor is disposed to promote evaporation of drain water.

  However, these first and second drain pans are fixed and can not be easily put in and out. For this reason, mold and bacteria may be generated in drain water accumulated in the first and second drain pans. This also causes an offensive odor.

  An object of an embodiment of the present invention is an open showcase capable of easily taking in and out a drain pan for receiving drain water, whereby drain water in the drain pan can be easily drained and the drain pan can be easily cleaned. To provide.

  The open showcase according to claim 1 comprises a display room for goods, and further comprises a cooling unit, a drain pan, a heating unit, a support mechanism, and a machine room. The cooling unit includes a refrigeration cycle configured by connecting a compressor, a condenser, a pressure reducer, and an evaporator, and cools the air in the display chamber. The drain pan is open at the top and receives drain water flowing down from the evaporator through the opening. The heating unit is accommodated in the drain pan and heats the drain water in the drain pan. The supporting mechanism supports the holding member for holding the heating unit in the drain pan through the opening of the drain pan and slidably supports the drain pan along a path detouring the drain pan with respect to the heating unit and the holding member. And a support member attached to the drain pan and supporting the slide of the drain pan in the base member, and the drain pan is supported in an extendable / retractable manner without interfering with the heating portion. The machine room has an opening for receiving the drain pan and for taking in and out the drain pan. The base member and the support member slide the drain pan obliquely downward while maintaining the horizontal state in accordance with the pulling operation of the drain pan, and the slide and the holding member are passed through the opening of the drain pan by the slide. Then, the drain pan is slid in a substantially horizontal direction, and the slide pan guides the drain pan to the opening side of the machine room through the lower side of the heating portion and the holding member. Further, the base member and the support member slide the drain pan in a substantially horizontal direction according to the operation of inserting the drain pan, and the slide passes the lower side of the heating unit and the holding member by the slide. The drain pan is slid obliquely upward, and the slide causes the heating portion and the holding member to enter the drain pan through the opening of the drain pan.

The figure which looked at the main part of one embodiment from the front side. The figure which looked at the main part of the embodiment from the side side. The figure which looked at the structure in the main body of the embodiment from the side by sectional view. The perspective view of the drain process unit in the embodiment, and its periphery part. The figure which looked at the partial cross section of the structure of FIG. 4, and was seen from the side. The perspective view which shows the structure of the drain pan in the embodiment, high temperature refrigerant | coolant piping P, and a support mechanism. The perspective view which decomposes | disassembles and shows the structure of the drain pan in the embodiment, a support member, high temperature refrigerant | coolant piping P, and a support mechanism. The figure which looked at the structure inside the machine room in the embodiment from the side side. The figure which shows concretely the mutual relationship of the drain pan in the same embodiment, a support member, high temperature refrigerant | coolant piping P, and a support mechanism. The perspective view which shows a mode that the drain pan in the embodiment is pulled out from a machine room. The perspective view which shows the state by which the drain pan in the embodiment was completely pulled out from the machine room.

Hereinafter, an embodiment of the present invention will be described based on the drawings.
[Configuration of the main body of the open showcase]
FIG. 1 is a front view of the appearance of the open showcase, and FIG. 2 is a side view of the appearance of the open showcase. The display room of the open showcase is a three-sided open type in which three surfaces, front, left and right, are open.

  The main unit 1 of the open showcase has a rectangular shape in a front view and a plan view. The main body 1 has a top 2 at the top and a machine room 3 at the bottom, and a display room 4 for goods between the top 2 and the machine room 3. The back surface 1a of the main body 1 is formed of a rectangular flat plate.

  The shape of the top 2 viewed from the front is a rectangle whose thickness in the vertical height direction is thin and whose dimension in the horizontal width direction is Fa. A ceiling surface 4 b of the display room 4 is formed by the lower surface of the top plate 2. The shape of the machine chamber 3 viewed from the front is a rectangle having a certain thickness in the vertical height direction and the dimension in the horizontal width direction being Fa. The upper surface of the machine room 3 is also the bottom 4 c of the display room 4. The shape of the display room 4 viewed from the front is long in the vertical height direction, and is a rectangle whose dimension in the horizontal width direction is Fa.

  The shape of the top 2 as viewed from the side is a rectangular shape having a small thickness in the vertical height direction and having a predetermined dimension in the front and rear depth direction by projecting from the rear surface 1a to the front side. The shape of the machine chamber 3 viewed from the side is a rectangular shape having a certain thickness in the vertical height direction and the dimension Fb in the front and rear depth direction. The dimension Fb in the depth direction of the machine room 3 is slightly longer than the dimension in the depth direction of the top 2.

  A back surface 4 a on the back side of the display room 4 is disposed with a gap of a predetermined size between the back surface 4 a and the back surface 1 a of the main body 1. The upper portion of the back surface 4a is substantially parallel to the back surface 1a. The portion other than the upper portion of the back surface 4a is slightly inclined so as to gradually come out to the front side as it goes downward.

  The display room 4 is a three-sided open type in which three surfaces, front, left, right, except the back 4a, the ceiling 4b, and the bottom 4c, are open. The front opening 401, the left opening 402, the right It has an opening 403. The display room 4 is exposed to the outside of the main body 1 through the front opening 401, the left side opening 402, and the right side opening 403.

  The dimensions of the main body 1 in the left-right width direction are the same as the dimensions of the top plate 2 in the left-right width direction and the dimensions of the machine room 3 in the left-right width direction. The dimension in the depth direction (front-rear direction) of the main body 1 is Fb, which is the same as the dimension in the depth direction (front-rear direction) of the machine room 3.

  A notification unit 9 for notifying that the drain water in the maintenance tray 36 described later is in a nearly full state is disposed on the top surface of the top 2.

[Internal configuration of main unit 1]
Below, the internal structure of the main body 1 is demonstrated. FIG. 3 is a cross-sectional view of the configuration in the main body 1 as viewed from the side.

  As described above, the back surface 4 a of the display room 4 is inclined so as to be gradually extended to the front opening 401 side from the ceiling surface 4 b to the bottom surface 4 c. On this back surface 4a, shelves 5 for placing products in a plurality of stages, for example, four stages are arranged at predetermined intervals in the vertical direction. The dimension in the left-right width direction of each shelf 5 is slightly shorter than the dimension in the left-right width direction of the back surface 4a. Each shelf 5 protrudes toward the front opening 401 while maintaining a substantially parallel state with the bottom surface 4 c. Goods for sale, for example, many canned drinks and bottled drinks are placed and displayed on the shelves 5. The space existing between the respective shelves 5 serves as a storage space for products on the respective shelves 5 and a space for cooling.

  On the back surface 4 a of the display room 4, cold air outlets 7 for blowing the cooling air (referred to as cold air) are formed at positions corresponding to the cooling spaces between the shelves 5. These cold air outlets 7 are openings formed in a U-shape as shown by a broken line in FIG. The cold air blown out from the cold air outlets 7 is sent to the goods on each shelf 5.

  Specifically, the cool air blower outlet 7 is horizontally elongated in the lateral width direction between the left and right side blowout portions 7ax and 7ay which are long in the vertical height direction and the side blowout portions 7ax and 7ay. And a center blowout portion 7b of a shape. The left side blowing portion 7ax is formed at the left end edge 4x of the back surface 4a. The left end edge 4x is adjacent to the left side opening 402. Right side blowing part 7ay is formed in right end edge 4y of back 4a. The right end edge 4 y is adjacent to the right side opening 403. The center blowing portion 7b is disposed at a position facing the upper portion of the cooling space, and is continuous with the upper portions of the side blowing portions 7ax and 7ay. The dimensions in the left-right width direction of the openings of the side blowout portions 7ax and 7ay are substantially equal to the dimensions in the vertical height direction of the opening of the center blowout portion 7b. The dimensions in the vertical height direction of the openings of the side blowout portions 7ax and 7ay are several times the dimensions in the vertical height direction of the opening of the center blowout portion 7b.

  The dimension from the left end to the right end of each cold air outlet 7 is slightly larger than the dimension in the lateral width direction of each shelf 5. With this configuration, the side blowout portions 7ax and 7ay correspond to the both end portions in the left-right width direction of each shelf 5 and the outside thereof. As a result, the cold air blown out from the side blowout portions 7ax and 7ay flows so as to touch the products placed on the both ends in the left-right width direction of each shelf 5.

  Even if it is a three-sided open display room 4 having a front opening 401, a left side opening 402, and a right side opening 403 by such cold air blowout, the product on each shelf 5 is uniform and efficient It can be cooled well.

  On the other hand, as shown in FIG. 2 and FIG. 3, a lighting unit 8 using a fluorescent lamp or a light emitting diode (LED) is disposed on the top plate 2 constituting the ceiling surface 4 b of the display room 4. The illumination unit 8 has a length along the upper edge of the front opening 401 of the display room 4, and illuminates the display room 4 and transmits the front surface of the top 2. On the front surface of the top plate 2, a trade name or the like of a product stored in the display room 4 is described. The description of this trade name is revealed by the illumination of the illumination unit 8.

  As shown by a broken line in FIG. 1, an air curtain outlet 10 is formed on the ceiling surface 4 b of the display room 4. The air curtain outlet 10 is a U-shaped opening along the front opening 401, the left side opening 402, and the right side opening 403.

  Specifically, the air curtain outlet 10 is horizontally elongated in the lateral width direction between the left side outlet 10ax and the right side outlet 10ay which are longitudinally elongated in the front and rear depth direction and the side outlets 10ax and 10ay. And a center blowout portion 10b of a shape. The left side blowing portion 10 ax is formed along the upper edge of the left side opening 402. The right side blowing portion 10 ay is formed along the upper edge of the right side opening 403. The center blowout portion 10b is formed along the upper edge of the front opening 401, and continues to the front end of the side blowout portions 10ax and 10ay.

  The cool air blown out from the center blowing portion 10 b flows from the upper side to the lower side along the front opening 401 of the display room 4. The cool air blown out from the side blowout portions 10ax and 10ay flows downward along the left side opening 402 and the right side opening 403 of the display room 4.

  The positions of the side outlet portions 10ax and 10ay are outside the positions of the side outlet portions 7ax and 7ay of the cold air outlet 7. The position of the center blowing portion 10 b is outside the position of the front end of each shelf 5. Therefore, the cool air blown out from the side blowout units 10ax and 10ay and the center blowout unit 10b flows downward without hitting the cold air blown out from the side blowout units 7ax and 7ay and without hitting each shelf 5. The flow of cold air blown out from the side blowout portions 10ax and 10ay and the center blowout portion 10b forms an air curtain along the front opening 401, the left side opening 402, and the right side opening 403 of the display room 4. The air curtain prevents external air from entering the display room 4 from the outside of the main body 1.

  As shown in FIG. 3, a duct 11 communicating with the air curtain outlet 10 is formed inside the top plate 2. The duct 11 guides the cold air supplied from the duct 12 on the back side of the back surface 4 a to the air curtain outlet 10.

  On the other hand, the suction port 13 is formed on the bottom surface 4 c of the display room 4. The suction port 13 is a U-shaped opening along the front opening 401, the left side opening 402, and the right side opening 403, and the cold air blown out from the respective cold air outlets 7 and the air curtain outlet 10 Inhale the cold air for the air curtain.

  Specifically, as shown by a broken line in FIG. 1, the suction port 13 has a long side in the front-rear depth direction between the left side suction portion 13ax and the right side suction portion 13ay, and the side suction portions 13ax and 13ay. And an elongated central suction portion 13b extending in the lateral width direction. The left side suction portion 13 ax is formed along the lower edge 402 b of the left side surface opening 402. The right side suction portion 13 ay is formed along the lower edge 403 b of the right side opening 403. The center suction portion 13 b is formed along the lower edge of the front opening 401 and continues to the front end of the side suction portions 13 ax and 13 ay.

  The positions of the side suction portions 13 ax and 13 ay of the suction port 13 and the center suction portion 13 b are outside the peripheral portion of each shelf 5. The positions of the side suction portions 13ax and 13ay of the suction port 13 are outside the positions of the side blowout portions 7ax and 7ay of the respective cold air outlets 7 in the lateral width direction. Due to this positional relationship, there is no obstacle on the flow path of the cold air between the air curtain outlet 10 and the inlet 13, and the cold air for the air curtain blown out from the air curtain outlet 10 is smooth and efficient at the inlet 13. I am sucked well. As a result, the air curtain can be stably formed.

  Further, as shown in FIG. 3, in a space between the back surface 4 a of the display room 4 and the back surface 1 a of the main body 1, a partition plate 19 formed of a heat insulating material such as expanded polystyrene is disposed. The space between the back surface 4 a and the back surface 1 a is divided by the partition plate 19 into a cold air circulation duct 12 and an exhaust duct 20. The ducts 12 and 20 extend in the vertical height direction of the main body 1.

  The upper portion of the duct 12 communicates with the air curtain outlet 10 via the duct 11 in the top plate 2. The lower portion of the duct 12 communicates with the duct 14 a in the machine chamber 3. The midway portion of the duct 12 communicates with the respective cold air outlets 7. The upper portion of the duct 20 communicates with an opening 21 formed between the top 2 and the back surface 1a. The lower portion of the duct 20 communicates with the internal space of the machine chamber 3.

  In the machine room 3, a compressor 15, a condenser 16, an expansion valve (pressure reducer) 17, and a fan 18 are disposed. Further, in the internal space of the machine room 3, the partition wall 14 is disposed in parallel with the upper surface of the machine room 3 (the bottom 4c of the display room 4). A duct 14 a is formed on the back side of the upper surface of the machine room 3 by the partition wall 14. The duct 14 a communicates the suction port 13 with the lower portion of the duct 12. A fan 22 for circulating cold air is disposed in the duct 14a. The fan 22 sucks air from the suction port 13 and sends the sucked air to the duct 12. Further, an evaporator 23 is disposed below the duct 12.

  The compressor 15, the condenser 16, the expansion valve 17, and the evaporator 23 are sequentially connected by a refrigerant pipe to constitute a refrigeration cycle. The compressor 15 sucks, compresses and discharges the refrigerant. The high temperature and high pressure gas refrigerant discharged from the compressor 15 flows to the condenser 16. The gas refrigerant that has flowed to the condenser 16 exchanges heat with the outside air sucked by the operation of the fan 18 and condenses. The liquid refrigerant flowing out of the condenser 16 flows to the evaporator 23 through the expansion valve 17 which is a pressure reducer. The liquid refrigerant flowing to the evaporator 23 exchanges heat with the air sent from the fan 22 and evaporates. The gas refrigerant flowing out of the evaporator 23 is sucked into the compressor 15.

  In the duct 12, a guide plate 25 is disposed at the opening upper edge of each cold air outlet 7. The guide plate 25 is L-shaped, and the standing portion is fixed to the back surface of the back surface 4 a, and the flat portion protrudes into the space inside the duct 12. A part of the cold air passing through the inside of the duct 12 is guided to the respective cold air outlets 7 by the guide plates 25.

  As indicated by a broken line in FIG. 3, the front of the machine room 3 is open, and the front cover plate 28 is attached to the opening so as to be openable / closable (removable). Both side surfaces of the machine room 3 are also opened, and side cover plates 29x and 29y are attached to these openings so as to be freely opened and closed (removable). The front cover plate 28 and the side cover plates 29x and 29y can be removed as needed for maintenance of parts in the machine room 3.

  The front cover plate 28 has a large number of punching holes 27 for introducing outside air. By the operation of the fan 18, the outside air is introduced into the machine room 3 through each punching hole 27. The introduced outside air rises in temperature through the condenser 16 and further cools the compressor 15 to a high temperature. The hot air flows through the duct 20 to the opening 21 and is discharged from the opening 21 to the outside of the main body 1.

[Configuration of drain processing unit 30]
The refrigeration cycle parts such as the compressor 15 and the like are disposed on the bottom surface 50 of the machine room 3 and the drain processing unit 30 is disposed. The configuration of the drain processing unit 30 will be described with reference to FIGS. 4 and 5. FIG. 4 is a perspective view of the drain processing unit 30 and its periphery. FIG. 5 is a side view of the configuration of FIG. 4 partially in cross section.

  The partition 14 forming the upper surface of the machine room 3 (the bottom 4c of the display room 4) is integrally formed with the partition 19 by the same heat insulating material as the partition 19.

  A blower guide plate 31 is disposed between the evaporator 23 and the partition 14 in the duct 12. The air flow guide plate 31 has a shape extending along the lateral width direction of the duct 12 and guides the air flow of the fan 22 to the evaporator 23. A drain hole 32 for discharging drain water flowing down from the evaporator 23 to the duct 14 a side is formed at the left end of the air flow guide plate 31 and at a position in contact with the upper surface of the partition 14. A drainage portion 33 for draining drain water flowing from the drainage hole 32 to the lower surface side of the partition 14 is formed at the left end of the partition 14.

  The drainage portion 33 includes a through hole penetrating the partition wall 14 from the upper surface side to the lower surface side, and a drainage pipe 33a fitted in the through hole. The lower portion of the drain pipe 33 a protrudes below the lower surface of the partition 14. Due to this protrusion, drain water flowing down from the drainage pipe 33 a does not adhere to the lower surface of the partition wall 14. A guide groove may be formed at a position between the drainage hole 32 and the drainage portion 33 on the upper surface of the partition 14 for efficiently flowing drain water.

  The spare drain container 34 is disposed below the drainage portion 33. A drain pan 35 is disposed at a position adjacent to the spare drain container 34 and at a position substantially at the same height as the spare drain container 34. Then, the maintenance tray 36 is placed below the preliminary drain container 34 and the drain pan 35 and at a predetermined position on the bottom surface 50 of the machine chamber 3. The spare drain container 34, the drain pan 35, and the maintenance tray 36 are box-shaped or dish-shaped containers each having a rectangular opening on the top surface.

  In addition, when the internal space of the machine room 3 is seen from the front side of the main body 1, the condenser 16 is arrange | positioned in the state which approached the right side edge part of the internal space. In the region between the left end in the internal space of the machine room 3 and the condenser 16, the spare drain container 34 and the maintenance tray 36 are arranged side by side up and down.

  The dimension of the spare drain container 34 in the left-right width direction is the same as the dimension of the maintenance tray 36 in the left-right width direction. The dimension in the depth direction of the spare drain container 34 is longer than the dimension in the depth direction of the condenser 16. The dimension in the depth direction of the maintenance tray 36 is longer than the dimension in the depth direction of the spare drain container 34 and longer than the dimension in the depth direction of the condenser 16. Among the dimensions in the depth direction (front-rear direction) of the maintenance tray 36, the dimension of the portion facing the drain pan 35 is equal to or greater than approximately half the dimension of the drain pan 35. The dimension in the depth direction (front-rear direction) of the maintenance tray 36 may be a size reaching the back surface (the back surface 1 a of the main body 1) of the machine room 3.

  The drain pan 35 is disposed from the left side area of the internal space of the machine room 3 to the area between the back side of the condenser 16 and the back side of the machine room 3. The combined shape of the drain pan 35 and the spare drain container 34 is substantially L-shaped along a part of the back surface of the condenser 16 and the left side surface of the condenser 16 when viewed from above.

  The height position of the bottom surface of the preliminary drain container 34 and the height position of the bottom surface of the drain pan 35 are the same. The dimension in the vertical height direction of the preliminary drain container 34 is larger than the dimension in the vertical height direction of the drain pan 35. A recess is formed in part of the upper edge of the back surface of the preliminary drain container 34, and a gutter-like drain water guide 34a is attached to the recess. The drain water guide 34 a has a shape extending from the rear surface of the preliminary drain container 34 to the top opening of the drain pan 35, and guides the drain water present in the upper portion in the preliminary drain container 34 to the drain pan 35. When the water level of the drain water accumulated in the preliminary drain container 34 reaches the drain water guide 34a, the drain water in the preliminary drain container 34 flows into the drain water guide 34a. The drain water flowing into the drain water guide 34 a flows into the drain pan 35 and falls. Therefore, the drain water collected in the spare drain container 34 is transferred to the drain pan 35 without overflowing from the spare drain container 34.

  That is, the preliminary drain container 34 receives drain water flowing down from the evaporator 23 and guides drain water of a predetermined amount or more among the received drain water to the drain pan 35.

  Over the bottom surface of the drain pan 35, an overflow pipe 35p is provided upright at a position facing the maintenance tray 36 and penetrating the bottom surface. The height position of the upper end (one end) of the overflow pipe 35 p is lower than the height position of the upper surface opening of the drain pan 35. The lower end (the other end) of the overflow pipe 35 p protrudes below the bottom surface of the drain pan 35. When the water level of the drain water accumulated in the drain pan 35 reaches the upper end of the overflow pipe 35p, the drain water in the drain pan 35 flows into the overflow pipe 35p. The drain water flowing into the overflow pipe 35 p flows down to the maintenance tray 36. Therefore, the drain water accumulated in the drain pan 35 is transferred to the maintenance tray 36 without overflowing from the drain pan 35. In addition, since the lower end of the overflow pipe 35p protrudes downward from the bottom surface of the drain pan 35, drain water flowing from the overflow pipe 35p does not adhere to the bottom surface of the drain pan 35.

  A drain water sensor 36 a is attached to the inner peripheral surface of the maintenance tray 36. The drain water sensor 36a detects that the drain water in the maintenance tray 36 has reached a predetermined height position, and wirelessly transmits a detection signal to that effect. The detection signal wirelessly transmitted is received by the notification unit 9 disposed on the top 2. When the notification unit 9 receives the detection signal of the drain water sensor 36a, the notification unit 9 emits the built-in light emitter, for example, a light emitting diode continuously or intermittently. By this light emission, the user is notified that the drain water in the maintenance tray 36 is in a nearly full state.

  On the other hand, the front surface of the spare drain container 34 includes a fixing portion 34 b extending vertically upward. The lower portion of the support plate 37 is screwed and fixed to the upper portion of the fixing portion 34b, and the fixing piece 37a at the upper portion of the support plate 37 abuts on the lower surface of the partition 14 and is screwed and fixed.

  The back of the spare drain container 34 includes hooks 34c extending vertically upward. An upper portion of the hook portion 34 c is a locking piece bent to the back side of the machine chamber 3. The locking piece of the hook portion 34c is supported on the lower surface of the partition 14 via the plate-like hanging plate 38. The hanging plate 38 has a locking piece bent at the front side of the machine chamber 3 at the bottom and a fixing piece bent at the back side of the machine chamber 3 at the top. The fixing piece at the upper portion of the hanging plate 38 is screwed and fixed to the lower surface of the partition 14, and the locking piece at the upper portion of the hook portion 34 c is placed on the locking piece at the lower portion of the hanging plate 38 It is locked.

  The hook portion 34 c of the spare drain container 34 only rests on the lower locking piece of the hanging plate 38. Therefore, by removing the front cover plate 28 of the machine room 3 and further unscrewing the fixing portion 34 b of the spare drain container 34 and the support plate 37, the spare drain container 34 can be pulled out to the front side of the main body 1. It is possible.

  The maintenance tray 36 only rests below the spare drain container 34 and the drain pan 35 and at a predetermined position on the bottom surface 50 of the machine room 3. Therefore, the maintenance tray 36 can be pulled out to the front side of the main body 1 only by removing the front cover plate 28 of the machine room 3.

[Configuration of drain pan 35 and support mechanism 40]
The drain processing unit 30 includes the air flow guide plate 31, the drainage hole 32, the drainage portion 33, the spare drain container 34, the drain pan 35, the maintenance tray 36, the support plate 37, and the suspension plate 38, as shown in FIGS. A support mechanism 40 and a high temperature refrigerant pipe (also referred to as a hot gas pipe) P are included. FIG. 6 is a perspective view showing the configuration of the drain pan 35, the high temperature refrigerant pipe P, and the support mechanism 40. As shown in FIG. FIG. 7 is an exploded perspective view showing the configuration of FIG.

  The drain pan 35 is a container formed in a box shape by the front surface portion 35x, the back surface portion 35y, the left side surface portion 35a, the right side surface portion 35b, and the bottom surface portion 35c. Through the top opening.

  The overflow pipe 35p is provided upright at a position near the front surface portion 35x in the bottom surface portion 35c. The dimension in the front-rear depth direction (X-X direction in FIG. 7) corresponding to the insertion direction and the extraction direction of the drain pan 35 is longer than the dimension in the horizontal width direction (Y-Y direction shown in FIG. 7) of the drain pan 35.

  The support mechanism 40 supports the drain pan 35 such that the drain pan 35 can be taken in and out without interference with the high temperature refrigerant pipe P. Specifically, the support mechanism 40 bypasses the high temperature refrigerant pipe P and the holding mechanisms 45 and 46 described later so that the drain pan 35 does not contact or collide with the high temperature refrigerant pipe P when the drain pan 35 is taken in and out. And the drain pan 35 is slidably supported. The support mechanism 40 is disposed in the region between the back surface of the condenser 16 and the back surface of the machine chamber 3 and on the bottom surface 50 of the machine chamber 3.

  The vertical surface of the L-shaped fitting 42 is fixed to the front surface 35 x of the drain pan 35. By this fixing, the lower surface side of the horizontal surface portion of the metal fitting 42 and the lower surface side of the bottom surface portion 35 c of the drain pan 35 become flush with each other. The total length of the fitting 42 is approximately half of the dimension of the drain pan 35 in the lateral width direction (Y-Y direction shown in FIG. 7). The fixing piece 43a on the upper edge of the standing plate 43 is screwed and fixed to the lower surface side of the horizontal surface portion of the metal fitting 42. The lower portion of the standing plate 43 is screwed and fixed to the lower edge of the left side opening 3x of the machine room 3. The drain pan 35 can be taken in and out through the left side opening 3x of the machine room 3.

  The support member 44 is fixed to the horizontal surface of the fitting 42 by screwing. The support member 44 supports the slide of the drain pan 35 in the base member 41, and the shape viewed from above is substantially L-shaped, and a horizontal surface portion 44a extending in the front-rear depth direction (X-X direction) of the drain pan 35 It includes a horizontal surface portion 44 b extending in the lateral width direction (Y-Y direction) of the drain pan 35. The length in the front-rear depth direction (X-X direction) of the horizontal surface portion 44 a is approximately half of the dimension in the front-rear depth direction (X-X direction) of the drain pan 35. The length in the lateral width direction (Y-Y direction) of the horizontal surface portion 44 b is substantially the same as the dimension in the lateral width direction (Y-Y direction) of the drain pan 35. The horizontal surface portions 44a and 44b are in close contact with the bottom surface portion 35c of the drain pan 35 in a surface contact state.

  Further, the support member 44 includes an inclined surface 44c bent at an acute angle so as to return from the rear end of the horizontal surface 44b to the front edge of the horizontal surface 44b, and a tip piece 44d formed at the front edge of the inclined surface 44c. . The angle θb between the inclined surface 44c and the horizontal surface 44b is hereinafter referred to as the inclination angle θb of the inclined surface 44c. The end piece 44d is bent substantially horizontally from the front end of the inclined surface 44c.

  The base member 41 slidably supports the drain pan 35 in a path detouring with respect to the high temperature refrigerant piping P and the holding members 45 and 46, and includes vertical surface portions (first and second vertical surface portions) 41a and 41b and a horizontal surface portion 41c. , Inclined surface 41d, stepped portion 41e, back surface 41f, restricting piece 41g, and side surface portions (first and second side surface portions) 41h and 41i.

  The vertical surface portions 41 a and 41 b are provided on the bottom surface 50 of the machine chamber 3 so as to face each other. The horizontal surface portion 41 c is disposed at a predetermined height position between the vertical surface portions 41 a and 41 b and slidably receives the bottom surface portion 35 c of the drain pan 35 and the support member 44. The inclined surface portion 41d rises obliquely upward from the rear end of the horizontal surface portion 41c, and slidably receives the insertion tip portion of the drain pan 35. The stepped portion 41 e extends substantially horizontally from the upper edge of the inclined surface portion 41 d in the insertion direction of the drain pan 35, and the insertion tip end portion of the drain pan 35 is placed thereon. The rear surface portion 41 f rises upward from the rear end of the stepped portion 41 e and receives the contact of the insertion end portion of the drain pan 35. The restriction piece 41g bends in the direction opposite to the insertion direction of the drain pan 35 from the upper edge of the back surface 41f, and restricts the upward movement of the insertion tip of the drain pan 35. The side surface portions 41h and 41i extend in the shape of a strip in the direction opposite to the insertion direction of the drain pan 35 from both sides of the back surface portion 41f and are connected to the upper portion of the vertical surface portions 41a and 41b. regulate.

  The vertical surface portion 41a has a fixing piece bent to the front side of the machine chamber 3 at the lower edge, and has a fixing piece bent to the back side of the machine chamber 3 at the upper edge. The vertical surface portion 41 b has a fixing piece bent to the back side of the machine chamber 3 at the lower edge and has a fixing piece bent to the front side of the machine chamber 3 at the upper edge. The fixing pieces at the lower part of the vertical surface portions 41 a and 41 b are screwed and fixed to the bottom surface 50 of the machine chamber 3.

  The horizontal surface portion 41c has fixing pieces bent upward, at both side edges. These fixing pieces are screwed and fixed to a substantially intermediate position in the height direction of the vertical surface portions 41a and 41b. By this fixing, the vertical surface portions 41a and 41b and the horizontal surface portion 41c are firmly connected.

  The inclined surface portion 41d is inclined at an angle θa with respect to the bottom surface portion 35c of the drain pan 35 to be inserted. The angle θa is hereinafter referred to as the inclination angle θa of the inclined surface portion 41d. The inclination angle θa is the same as the inclination angle θb of the inclined surface portion 44c of the support member 44.

  The front end portions of the side surface portions 41h and 41i are screwed and fixed to the vertical surface portions 41a and 41b. By this fixing, the inclined surface portion 41d, the stepped portion 41e, and the back surface portion 41f are firmly connected to the vertical surface portions 41a and 41b.

  The base member 41 supports the drain pan 35 at three points. That is, the insertion tip (rear surface 35y) of the drain pan 35 is placed on the stepped portion 41e. The tip end 44d of the support member 44 on the lower surface side of the drain pan 35 is placed on the horizontal surface 41c. The front surface portion 35 x of the drain pan 35 is fixed to the lower edge of the left side opening 3 x of the machine room 3 by the fitting 42 and the standing plate 43.

  Further, the base member 41 supports the plate-like holding members (first and second holding members) 45 and 46. The holding members 45 and 46 hold the high temperature refrigerant pipe P in the drain pan 35 through the upper surface opening of the drain pan 35 and hold the upper surface of the base member 41 in a state where the plate surfaces are vertically superimposed. Mounted on The high temperature refrigerant pipe P is disposed between the holding members 45 and 46. The high-temperature refrigerant pipe P is a part of the refrigerant pipe that guides the high-temperature high-pressure gas refrigerant discharged from the compressor 15 to the condenser 16, and is formed in a serpentine shape by bending a plurality of times.

  Of the holding members 45 and 46, the lower holding member 46 is a horizontal surface 46c on which the high temperature refrigerant pipe P is mounted, vertical surfaces 46a and 46b rising upward from both sides of the horizontal surface 46c, and oblique from the rear end of the horizontal surface 46c. It includes an inclined surface portion 46d rising upward. The vertical surface portion 46 a has a fixing piece bent at the side of the vertical surface portion 41 a of the base member 41 at the upper edge. The vertical surface portion 46 b has a fixing piece bent at the side of the vertical surface portion 41 b of the base member 41 at the upper edge.

  The holding member 45 includes a horizontal surface 45 c for holding the high temperature refrigerant pipe P, and vertical surfaces 45 a and 45 b which rise upward from both sides of the horizontal surface 45 c. The vertical surface 45 a has a fixing piece bent at the side of the vertical surface 41 a of the base member 41 at the upper edge. The vertical surface portion 45 b has a fixing piece bent at the side of the vertical surface portion 41 b of the base member 41 at the upper edge.

  The fixing pieces of the vertical surface portions 45a and 45b of the holding member 45 are screwed to the fixing pieces of the upper edge of the vertical surface portions 41a and 41b in a state where the fixing pieces overlap with the fixing portions of the vertical surface portions 46a and 46b of the holding member 46 Be done. By this fixing, the holding members 45 and 46 are supported by the base member 41, and the high temperature refrigerant pipe P is held between the holding members 45 and 46 in a sandwiched state.

  The serpentine high temperature refrigerant pipe P has a large shape, but since the high temperature refrigerant pipe P is sandwiched between the surface of the holding member 45 and the surface of the holding member 46 in the direction orthogonal to the meandering direction, Even in the case of the large shape, the high temperature refrigerant pipe P can be reliably and firmly held. For example, even if vibration of transportation at the time of shipping the main body 1 from a manufacturing factory is applied to the main body 1, the high temperature refrigerant pipe P is firmly held by the holding members 45 and 46 and does not move.

  In the state where the holding members 45 and 46 are attached to the base member 41, the holding members 45 and 46 enter the drain pan 35 through the top opening of the drain pan 35 together with the high temperature refrigerant pipe P. Specifically, the horizontal surface portion 46c of the lower holding member 46 is in contact with the bottom surface portion 35c of the drain pan 35 or at a position slightly higher than the bottom surface portion 35c. Therefore, if even a little drain water is accumulated in the drain pan 35, the drain water contacts the horizontal surface 46 c of the holding member 46. Since the high temperature refrigerant pipe P is mounted on the horizontal surface 46c, the heat of the high temperature refrigerant pipe P is transmitted to the drain water directly or through the horizontal surface 46c. Thereby, the drain water in the drain pan 35 is heated. The heated drain water evaporates gradually. The heat of the high-temperature refrigerant pipe P can be efficiently transmitted to the drain water by forming the holding members 45 and 46 with a member having good thermal conductivity.

  The base member 41 and the support member 44 slide the drain pan 35 obliquely downward according to the pulling operation of the drain pan 35, and the slide of the high temperature refrigerant pipe P and the holding members 45, 46 through the upper surface opening of the drain pan 35 by this slide Then, the drain pan 35 is slid in a substantially horizontal direction, and the slide pan guides the drain pan 35 to the side opening 3x side of the machine room 3 through the lower side of the high temperature refrigerant pipe P and the holding members 45, 46.

  The base member 41 and the support member 44 slide the drain pan 35 in a substantially horizontal direction according to the operation of inserting the drain pan 35, and the slide pan passes the lower side of the high temperature refrigerant pipe P and the holding members 45 and 46 by this slide. The side of the machine room 3 is guided to the opposite side to the side opening 3x, and then the drain pan 35 is slid obliquely upward, and the slide causes the high temperature refrigerant pipe P and the holding members 45, 46 to pass through the top opening of the drain pan 35 into the drain pan 35. Get in.

  On the other hand, the evaporation member G is detachably mounted on the bottom portion 35c of the drain pan 35 and in the region between the overflow pipe 35p and the high temperature refrigerant pipe P in a standing position.

  The evaporation member G has high water absorbability and excellent transpiration of absorbed water, and is formed, for example, by stacking a plurality of rectangular non-woven fabrics. The drain water in the drain pan 35 is heated by the high-temperature refrigerant pipe P to rise in temperature, and is gradually evaporated as it is, and a part thereof is absorbed by the evaporation member G. The sucked drain water is heated by the high-temperature refrigerant pipe P and rises in temperature, so it efficiently and quickly evaporates from the evaporation member G.

  The dimension in the vertical height direction of the evaporation member G is much larger than the dimension in the vertical height direction of the front surface portion 35 x of the drain pan 35. Therefore, only the lower end portion of the evaporation member G enters the drain pan 35, and most of the evaporation member G protrudes upward from the top opening of the drain pan 35. There is no configuration for supporting this projecting portion, and the evaporation member G is self-supporting on the bottom surface portion 35 c of the drain pan 35.

[Drain water generation]
The high temperature / high pressure gas refrigerant discharged from the compressor 15 flows to the condenser 16 through the high temperature refrigerant pipe P. The gas refrigerant that has flowed to the condenser 16 exchanges heat with the outside air sucked by the operation of the fan 18 and condenses. The liquid refrigerant flowing out of the condenser 16 flows through the expansion valve 17 to the evaporator 23. The liquid refrigerant flowing to the evaporator 23 exchanges heat with the air sent from the fan 22 and evaporates. The gas refrigerant flowing out of the evaporator 23 is sucked into the compressor 15.

  The air sent from the fan 22 to the evaporator 23 contains moisture, and the moisture adheres to the surface of the evaporator 23 as water droplets. The deposited water droplets gradually increase and eventually drain water from the evaporator 23 as drain water. Moreover, a part of the water droplet adhering to the surface of the evaporator 23 freezes and becomes frost. In order to remove the frost, the operation of the refrigeration cycle (the operation of the compressor 15) is stopped periodically or as necessary. The frost melted by the shutdown is drained from the evaporator 23 as drain water as shown by an arrow in FIG.

  The drain water flowing down from the evaporator 23 collects in the lower part in the duct 12. The accumulated drain water flows through the drainage holes 32 of the air flow guide plate 31 and further along the partition wall 14 and flows into the drainage portion 33, as shown by the arrows in FIG. The drain water having flowed into the drainage portion 33 falls into the spare drain container 34 through the drain pipe 33 a and is accumulated in the spare drain container 34.

  The temperature of the drain water is considerably low immediately after leaving the evaporator 23, but rises to a certain degree while remaining in the lower part in the duct 12, and further rises to some extent while flowing from the drainage hole 32 to the drainage portion 33. Do. Then, the temperature of the drain water accumulated in the preliminary drain container 34 rises to the ambient temperature (indoor temperature) of the store where the main body 1 is installed.

  As the drain water in the spare drain container 34 approaches full, drain water in the spare drain container 34 flows into the drain pan 35 through the drain water guide 34 a. The drain water accumulated in the drain pan 35 rises in temperature due to the heat of the high temperature refrigerant pipe P, and gradually evaporates, and a part thereof is absorbed and evaporated by the evaporation member G.

  In particular, the temperature of the drain water accumulated in the drain pan 35 has already risen to the atmosphere temperature of the store at the time of moving from the preliminary drain container 34 to the drain pan 35. To efficiently and quickly rise to a possible state.

  When the amount of drain water transferred from the preliminary drain container 34 to the drain pan 35 exceeds the amount of drain water evaporated from the drain pan 35 and the amount of drain water transpirationed from the evaporation member G, the water level of the drain water in the drain pan 35 rises Do. When the drain water level in the drain pan 35 reaches the upper edge of the overflow pipe 35p, the drain water in the drain pan 35 flows to the maintenance tray 36 through the overflow pipe 35p.

[Full notification of drain water]
When the drain water level in the maintenance tray 36 reaches a predetermined height position, it is detected by the drain water sensor 36a. Based on this detection, the light emitting diodes in the notification unit 9 disposed on the top surface of the top 2 emit light continuously or intermittently. This light passes through the cover of the notification unit 9 and spreads around. As a result, the user is notified that the drain water in the maintenance tray 36 is almost full.

  The user who has recognized the notification removes the front cover plate 28 of the machine room 3 and pulls the maintenance tray 36 out of the main body 1 through the front opening 3 a of the machine room 3. Since the maintenance tray 36 only rests on the bottom surface 50 of the machine room 3, the withdrawal of the maintenance tray 36 is easy. Then, the user drains the drain water in the maintenance tray 36.

  After draining water, the user returns the maintenance tray 36 to its original position in the machine room 3 and mounts the front cover plate 28.

[maintenance]
The service person in charge of the maintenance of the main body 1 visits the store where the main body 1 is installed and the front cover of the machine room 3 when a predetermined maintenance time comes or when the user receives a maintenance request from the user The plate 28 is removed and the maintenance tray 36 is pulled out of the main body 1 through the front opening 3 a of the machine room 3. Then, the service person drains the drain water in the maintenance tray 36 and cleans the inside of the maintenance tray 36.

  Further, the serviceman releases the screwing of the fixing portion 34 b of the spare drain container 34 and the support plate 37 and pulls the spare drain container 34 out of the main body 1 through the front opening 3 a of the machine room 3. Since the hook portion 34c of the spare drain container 34 only rests on the locking piece of the suspension plate 38, it is easy to withdraw the spare drain container 34. Then, the service person drains the drain water in the spare drain container 34 and cleans the inside of the spare drain container 34.

  The serviceman also removes the side cover plate 29x of the machine room 3. By this removal, the inside of the machine room 3 is exposed through the left side opening 3x as shown in FIG. In addition, illustration of the member G for evaporation is abbreviate | omitted in FIG.

  Subsequently, the serviceman releases the screwing between the metal fitting 42 and the standing plate 43, and releases the screwing between the standing plate 43 and the left side opening 3x. At this point, the support state of the drain pan 35 on the base member 41 changes from the previous three-point support to the two-point support. In the two-point support, the insertion tip (rear surface 35y) of the drain pan 35 is mounted on the step 41e of the base member 41, and the tip 44d of the support member 44 on the lower surface of the drain pan 35 is a horizontal surface of the base 41 It's about being on 41c. The drain pan 35 maintains a substantially horizontal state even when the two points are supported. Therefore, even if the drain water in the drain pan 35 is in a nearly full state, the problem that the drain water flows out from the drain pan 35 does not occur.

  The serviceman holds the front portion 35x side of the drain pan 35 and pulls the drain pan 35 out of the main body 1 through the left side opening 3x of the machine room 3 as shown in FIGS.

  At the time of the pull-out operation, first, the end piece 44 d of the support member 44 comes out of the front end of the horizontal surface 41 c of the base member 41, and the bottom 35 c of the drain pan 35 moves from the step 41 e of the base 41 to the inclined surface 41 d. Subsequently, the inclined surface 44c of the support member 44 slides obliquely downward while in contact with the front end of the horizontal surface 41c of the base member 41, and the boundary (corner) between the bottom 35c and the back 35y of the drain pan 35 is inclined. It slides obliquely downward while in contact with the surface portion 41d. That is, the entire drain pan 35 slides downward in a slanting direction. In this case, since the inclination angle θb of the inclined surface portion 44c of the support member 44 and the inclination angle θa of the inclined surface portion 41d of the base member 41 are the same, the drain pan 35 slides downward obliquely while maintaining the substantially horizontal state. The holding members 45 and 46 and the high temperature refrigerant pipe P do not move while being supported by the base member 41.

  When the drain pan 35 continues to be pulled out, the inclined surface 44c of the support member 44 eventually comes out of the horizontal surface 41c of the base member 41, and the bottom 35c of the drain pan 35 comes to rest on the horizontal surface 41c of the base 41. The bottom 35 c of the drain pan 35 slides on the horizontal surface 41 c of the base member 41. The holding members 45 and 46 and the high temperature refrigerant pipe P are separated from the inside of the drain pan 35 through the top opening of the drain pan 35.

  The serviceman lifts the evaporation member G placed on the drain pan 35 upward and takes it out.

  When the operation of pulling out the drain pan 35 further continues, the bottom 35c of the drain pan 35 slides on the horizontal surface 41c of the base member 41, and the drain pan 35 passes below the holding members 45 and 46 and the high temperature refrigerant pipe P. Thereby, as shown in FIG. 11, the drain pan 35 can be pulled out of the main body 1 through the left side opening 3x of the machine room 3. In this case, by holding the drain pan 35 with both hands so that the drain pan 35 does not tilt, drain water in the drain pan 35 does not overflow.

  The serviceman carries the drain pan 35 pulled out to the drain water disposal site, discards the drain water in the drain pan 35, and cleans the inside of the drain pan 35. Furthermore, the serviceman cleans the taken-out evaporation member G as well. The removed evaporation member G may be replaced with a new evaporation member G.

  After the series of maintenance including cleaning is completed, the serviceman places the drain pan 35 on the horizontal surface portion 41 c of the base member 41 in the machine room 3 and inserts it.

  At the initial stage of this insertion operation, the bottom 35 c of the drain pan 35 slides on the horizontal surface 41 c of the base member 41, and the drain pan 35 passes below the holding members 45 and 46 and the high temperature refrigerant pipe P. Subsequently, as shown in FIG. 9, the inclined surface 44 c of the support member 44 slides obliquely upward while in contact with the front end of the horizontal surface 41 c of the base member 41, and the boundary between the bottom 35 c and the back 35 y of the drain pan 35 The portion (corner portion) slides obliquely upward while in contact with the inclined surface portion 41d. That is, the entire drain pan 35 slides upward in a slanting manner.

  When the operation of inserting the drain pan 35 continues, the end piece 44d of the support member 44 comes to rest on the front end side of the horizontal surface 41c of the base member 41, and the bottom 35c of the drain pan 35 rests on the step 41e of the base member 41. It will be The back surface 35 y of the drain pan 35 abuts on the back surface 41 f of the base member 41. By this contact, the insertion of the drain pan 35 is completed. The holding members 45 and 46 and the high temperature refrigerant pipe P enter the drain pan 35 through the upper opening of the drain pan 35.

  After the drain pan 35 is completely inserted, the serviceman places the cleaned or new evaporation member G in the drain pan 35. Thereafter, the serviceman mounts the fitting 42 and the standing plate 43, and further mounts the side cover plate 29x. Subsequently, the serviceman inserts the spare drain container 34 from the front opening 3 a of the machine room 3 and attaches the fixing portion 34 b and the support plate 37. Further, the serviceman inserts the maintenance tray 36 from the front opening 3a of the machine room 3 and attaches the front cover plate 28. This is the end of maintenance.

  As described above, the drain pan 35 is lowered according to the pulling operation of the drain pan 35, and the high temperature refrigerant pipe P and the holding members 45, 46 are separated from the inside of the drain pan 35 by this lowering. Since the high temperature refrigerant pipe P and the holding members 45 and 46 are made to enter the drain pan 35 by raising 35, the drain pan 35 contacts or collides with the high temperature refrigerant pipe P and the holding members 45 and 46. Instead, the drain pan 35 can be easily and smoothly put in and out.

  Since the drain pan 35 can be put in and out by a simple operation of pulling out the drain pan 35 in one direction and inserting it in the opposite direction, not only a service man who is used to the operation but also general users who are not used to the operation It can be put in and out easily and smoothly. Therefore, drain pan 35 can be cleaned easily at any time. As a result, the generation of mold and bacteria in the drain pan 35 can be prevented, and the offensive odor can also be prevented.

  Since the sliding drain pan 35 is supported in a substantially horizontal state by the sloped surface portion 41 d of the base member 41 and the sloped surface portion 44 c of the support member 44, the drainage water in the drain pan 35 can be prevented from overflowing into the machine chamber 3. .

  In the above embodiment, although the three-sided open type open showcase has been described as an example, the present invention is not limited thereto, and the present invention can be similarly applied to a general one-sided open type open showcase open only at the front side. .

  In the above embodiment, the high-pressure refrigerant pipe through which the refrigerant discharged from the compressor 15 directly flows is used as the high-temperature refrigerant pipe P as the heating unit for heating drain water in the drain pan 35. However, a high temperature refrigerant flows If it is refrigerant piping, you may use refrigerant piping of other parts as high temperature refrigerant piping P. Moreover, as a heating part, you may use not only refrigerant | coolant piping but an electric heater, for example.

  In the above embodiment, the notification unit 9 arranged on the top plate 2 of the main body 1 reports that the drain water in the maintenance tray 36 is in a nearly full state, but as the notification means, Not limited to the light emitting diode, a buzzer that emits an electronic sound may be used. Both a light emitting diode and a buzzer may be used as notification means. Further, in addition to using a light emitting diode or a buzzer as a notification means, a notification signal to the effect that drain water in the maintenance tray 36 is in a nearly full condition is sent from the notification unit 9 to the management room of the store, etc. It is also possible to send via a communication network.

  In addition, the above embodiments and modifications are presented as examples, and are not intended to limit the scope of the embodiments and modifications. This novel embodiment and variations can be implemented in other various forms, and various omissions, substitutions and changes can be made without departing from the scope of the present invention. These embodiments and modifications are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  The open showcase according to the embodiment of the present invention can be used in stores such as small convenience stores and relatively small supermarkets.

The open showcase according to claim 1 comprises a display room for goods, and further comprises a cooling unit, a drain pan, a heating unit, a support mechanism, and a machine room. The cooling unit includes at least an evaporator of a refrigeration cycle configured by connecting a compressor, a condenser, a pressure reducer, and an evaporator, and cools the air in the display chamber. The drain pan is open at the top and receives drain water flowing down from the evaporator through the opening. The heating unit is accommodated in the drain pan and heats the drain water in the drain pan. The support mechanism includes a base member for supporting the drain pan slidably in a path that bypasses against the above heating unit, and a support member that supports the sliding of the drain pan in the base member attached to the drain pan, the drain pan Is freely supported without interfering with the heating unit. The machine room has an opening for receiving the drain pan and for taking in and out the drain pan. The base member is disposed between the first and second vertical surface portions erected to face each other on the bottom surface of the machine chamber; and is disposed between the first and second vertical surface portions and slides on the bottom surface of the drain pan A horizontal surface freely received; a sloped surface rising obliquely upward from the horizontal surface and slidably receiving the insertion tip of the drain pan; and extending horizontally from the upper edge of the sloped surface in the insertion direction of the drain pan, A stepped portion on which the insertion end portion of the drain pan is mounted; a back portion rising upward from the step portion and in contact with the insertion end portion of the drain pan; and from both sides of the back portion opposite to the insertion direction of the drain pan The first and second side surface portions extend in a direction and are connected to the first and second vertical surface portions to restrict movement of the drain pan in a direction orthogonal to the insertion direction. The support member has a flat surface portion attached to the bottom surface portion of the drain pan; and an inclined surface portion bent from the flat surface portion in a direction opposite to the insertion direction of the drain pan and slidably contacting the horizontal surface portion of the base member Including. Then, the base member and the support member in accordance with the withdrawing operation of the drain pan, and slide the drain pan obliquely downward, the heating unit is detached from within the drain pan through the opening of the drain pan by the slide, followed by Te slide in a substantially horizontal direction above the drain pan lead to the drain pan by the slide on the opening side of the machine chamber through the lower side of the heating unit. Furthermore, the base member and the support member in response to operation of inserting the drain pan, substantially slide horizontally the drain pan, the opening of the machine room the drain pan through the lower side of the heating unit by the slide and it led to the opposite side, followed by sliding the drain pan obliquely upward, the heating unit to enter into the drain pan through the opening of the drain pan by the slide.

Claims (9)

Product display room,
A cooling unit including a refrigeration cycle configured by connecting a compressor, a condenser, a pressure reducer, and an evaporator, and cooling air in the display chamber;
A drain pan open at the top and receiving drain water flowing down from the evaporator through the opening;
A heating unit accommodated in the drain pan and heating the drain water in the drain pan;
A holding member for holding the heating portion in the drain pan through the opening of the drain pan, and a base member slidably supporting the drain pan in a path bypassing the heating portion and the holding member; A support member attached to the drain pan and supporting the slide of the drain pan on the base member, the support mechanism supporting the drain pan so as to be able to be inserted and removed without interfering with the heating unit;
A machine room having an opening for receiving the drain pan and for taking the drain pan in and out;
Equipped with
The base member and the support member are
According to the operation of pulling out the drain pan, the drain pan is slid obliquely downward while maintaining the horizontal state, and the slide causes the heating unit and the holding member to be separated from the inside of the drain pan through the opening of the drain pan The drain pan is slid in a substantially horizontal direction, and the slide leads the drain pan to the opening side of the machine room through the lower side of the heating unit and the holding member.
According to the operation of inserting the drain pan, the drain pan is slid in a substantially horizontal direction, and the slide leads the drain pan through the lower side of the heating unit and the holding member to the opposite side of the opening of the machine chamber Slide the drain pan obliquely upward, and this slide causes the heating unit and the holding member to enter the drain pan through the opening of the drain pan.
An open showcase characterized by A preliminary drain container for receiving drain water flowing down from the evaporator and guiding drain water of a predetermined amount or more among the received drain water to the drain pan;
The open showcase according to claim 1, further comprising: The base member is
First and second vertical surface portions erected to face each other on the bottom surface of the machine room;
A horizontal surface portion disposed between the first and second vertical surface portions and slidably receiving the bottom surface of the drain pan;
An inclined surface portion rising obliquely upward from the horizontal surface portion and slidably receiving an insertion tip portion of the drain pan;
A step which extends horizontally from the upper edge of the inclined surface in the insertion direction of the drain pan and on which the insertion tip of the drain pan rests;
A rear surface portion rising upward from the stepped portion and in contact with an insertion tip portion of the drain pan;
First and second portions extending from both sides of the back surface in a direction opposite to the insertion direction of the drain pan and connected to the first and second vertical surface portions to restrict movement of the drain pan in a direction orthogonal to the insertion direction Side part,
Including
The support member is
A flat portion attached to the bottom of the drain pan;
An inclined surface portion bent from the flat surface portion in a direction opposite to the insertion direction of the drain pan and slidably contacting the horizontal surface portion of the base member;
Including
The inclination angle of the inclined surface of the base member is the same as the inclination angle of the inclined surface of the support member.
The open showcase according to claim 1, characterized in that: The heating unit is a high-temperature refrigerant pipe, and is a part of a refrigerant pipe that guides high-temperature gas refrigerant discharged from the compressor to the condenser.
The holding member is a plate-shaped first and second holding member for holding the high temperature refrigerant pipe in a sandwiched state.
The open showcase according to any one of claims 1 to 3, characterized in that: An evaporation member which is detachably mounted in the drain pan and sucks up and evaporates the drain water in the drain pan;
Further comprising
The open showcase according to claim 1, characterized in that: The cooling unit is
The refrigeration cycle;
A fan that sucks in air from the display room and sends it to the evaporator;
A duct which accommodates the evaporator and guides cold air passing through the evaporator to the display chamber;
including,
The open showcase according to claim 1, characterized in that: A drainage portion for draining drain water which flows down from the evaporator and accumulates in the duct;
A preliminary drain container for temporarily receiving drain water discharged from the drain portion and guiding it to the drain pan;
including,
The open showcase according to claim 6, characterized in that: An overflow pipe for discharging drain water of a predetermined amount or more out of the drain water in the drain pan to the outside of the drain pan;
A maintenance tray for receiving drain water discharged from the overflow pipe;
The open showcase according to claim 1, further comprising: A drain water sensor that detects when the level of drain water in the maintenance tray reaches a predetermined position;
A notification unit for notifying that the drain water in the maintenance tray is nearly full according to the detection of the drain water sensor;
The open showcase according to claim 8, further comprising:

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