JP2014055721A - Refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigerator configured to prevent a bottom plate of a machine room from being deformed during transportation.SOLUTION: A refrigerator includes: a heat insulation box disposed above a cabinet so as to form a storage room; and a machine room disposed below the cabinet. The refrigerator is disposed on an installation surface. A rear end corner part of the bottom plate constituting a bottom wall of the machine room has a plurality of mount parts that serve as contact parts brought into contact with the installation surface when the cabinet is inclined and are disposed in the inclination direction.

Description

  The present invention relates to a refrigerator including a cabinet in which a machine room is provided on the lower side.

  A conventional refrigerator is disclosed in Patent Document 1. This refrigerator includes a main body part in which a plurality of storage chambers are formed by a heat insulating box filled with a heat insulating material. The front of each storage room is opened and closed by a heat insulating door. A machine room disposed below the heat insulating box is provided in the lower rear portion of the main body.

Japanese Patent Laid-Open No. 2-136669

  When transporting this type of refrigerator, the refrigerator is first tilted backward so that the insulated door does not open or close during transport. Thereafter, the refrigerator is gradually tilted and raised to a substantially horizontal state. From the time when the refrigerator is tilted rearward until the refrigerator is lifted, only the rear end corner of the bottom plate constituting the bottom wall of the machine room contacts the floor surface.

  Further, the rear end corner portion of the bottom plate is formed in a substantially right angle when viewed from the side. Therefore, the weight of the refrigerator is applied to only a part of the rear end corner of the bottom plate after the refrigerator is tilted rearward until the refrigerator is lifted. As described above, there is a problem that the bottom plate is deformed when the weight of the refrigerator is loaded only on a part of the rear end corner portion of the bottom plate for a long time.

  An object of the present invention is to provide a refrigerator in which a bottom plate of a machine room is not deformed during transportation.

  In order to achieve the above object, a refrigerator according to the present invention is provided on an installation surface, and includes a heat insulating box provided on an upper side of a cabinet to form a storage room, and a machine room provided on the lower side of the cabinet. In the refrigerator, the rear end corner portion of the bottom plate constituting the bottom wall of the machine room has a plurality of crest portions that are contact portions that come into contact with the installation surface when the cabinet is tilted in the tilt direction.

  Moreover, this invention is a refrigerator of the said structure. WHEREIN: The said peak part contains the 1st peak part and the 2nd peak part located in the upper side and back side of the said 1st peak part.

  In the refrigerator having the above-described configuration, when the cabinet is tilted, the inclination angle of the cabinet where the second peak portion contacts the installation surface is such that the center line of the cabinet is the second peak portion. The inclination angle is larger than the inclination angle of the cabinet passing through.

  Moreover, this invention is a refrigerator of the said structure, The said rear-end corner | angular part is formed in a stepped shape.

  According to the present invention, in the refrigerator configured as described above, the mountain portion has a round shape.

According to the present invention, the refrigerator is provided on the upper side of the cabinet and forms a storage room, and a heat insulating box,
A refrigerator provided on the installation surface with a machine room provided on the lower side of the cabinet, the rear end corner of the bottom plate constituting the bottom wall of the machine room is installed when the cabinet is tilted There are a plurality of crests serving as contact portions in contact with the inclining direction. With this configuration, when the refrigerator is tilted for transportation, the weight of the refrigerator is applied to different parts depending on the tilt angle, and only a part of the bottom plate is not loaded. Therefore, deformation of the bottom plate can be prevented.

The front view which shows the refrigerator of embodiment of this invention Side surface sectional drawing which shows the refrigerator of embodiment of this invention Top surface sectional drawing which shows the back side of the refrigerator of embodiment of this invention The perspective view which looked at the machine room of the refrigerator of the embodiment of the present invention from the back Perspective view of cover member Rear view of cover member Side view of cover member Side sectional view of the bottom plate that forms the bottom wall of the machine room Schematic diagram showing reaction force and component force The schematic diagram which shows the state which the 2nd peak part and the floor surface contacted

<First Embodiment>
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a front view showing a refrigerator according to an embodiment. FIG. 2 is a side sectional view showing the refrigerator according to the embodiment. FIG. 3 is a top sectional view showing the back side of the refrigerator according to the embodiment. The cabinet 2 of the refrigerator 1 has a heat insulation box which constitutes a storage room for storing stored items. The heat insulating box includes an inner box 20, an outer box 21, and a heat insulating material filled between the inner box 20 and the outer box 21. As the heat insulating material, a vacuum heat insulating material (VIP) 30 and a foam heat insulating material 31 are used in combination.

  The vacuum heat insulating material 30 has a lower thermal conductivity than the foam heat insulating material 31 and can obtain a high heat insulating effect with a small amount. On the other hand, it is known that the heat insulating performance of the vacuum heat insulating material 30 gradually deteriorates due to the generation of gas from the inside with the passage of time and the penetration and penetration of external gas. Therefore, it is desirable to use not only the vacuum heat insulating material 30 but also the foam heat insulating material 31 in which the heat insulating performance is less likely to deteriorate with time. The vacuum heat insulating material 30 is manufactured by inserting a fiber-based core material into an outer packaging material and sealing the inside with reduced pressure, and the core material is hard and brittle, so that it is difficult to bend and productivity is increased. It is manufactured in a planar shape in consideration. Therefore, in this embodiment, the linear vacuum heat insulating material 30 is bonded and fixed to the flat portion 211 as described later.

  The outer box 21 includes a side wall (side plate) 21a and a back wall (back plate) 21b. The back wall 21b has a flat surface portion 211 to which the vacuum heat insulating material 30 is bonded and fixed, and a foam heat insulating material 31 (hereinafter referred to as foam heat insulating material in the present embodiment). A foamed polyurethane heat insulating material, which is an example of a material, is used, and the inclined portion 212 and the side wall 21a having an inlet 212a for injecting the “foamed heat insulating material 31” may be referred to as “foamed polyurethane heat insulating material 31”. Is provided with an attachment portion 213 to which is attached.

  The attachment portions 213 are formed at both ends of the back wall 21b, are formed substantially parallel to the surface direction of the flat surface portion 211, and are jig receiving portions 213a facing the jig 214a of the attachment portion 214 provided in the side wall 21a, It has an insertion part 213b that is formed substantially perpendicular to the surface direction of the flat part 211 and is inserted into the substantially U-shaped insertion groove 214b of the attachment part 214 provided in the side wall 21a. The side wall 21a has a flat portion 215 to which the vacuum heat insulating material 30 is bonded and fixed, and an attachment portion 214 that is formed at the end of the flat portion 215 on the back wall 21b side. The attachment portion 214 of the side wall 21a has an insertion groove 214b whose one end is connected to the flat portion 215, and a jig 214a that is formed to extend from the other end of the insertion groove 214b substantially perpendicularly to the surface direction of the flat portion 215. .

  When the side wall 21a is attached to the back wall 21b, gaps are formed between the jig 214a and the jig receiving portion 213a, and between the insertion groove 214b and the insertion portion 213b, into which the polyurethane foam heat insulating material 31 can flow. As will be described later, when the polyurethane foam heat insulating material 31 is injected from the inlet 212a, the polyurethane polyurethane heat insulating material 31 flows into this gap. The foamed polyurethane heat insulating material 31 that has flowed into the gap is foamed, so that the attachment portions 213 and 214 are bonded to each other.

  The inner box 20 has a back wall 20 b that faces the flat surface portion 211 of the back wall 21 b of the outer box 21 and a side wall 20 a that faces the flat surface portion 215 of the side wall 21 a of the outer box 21. The foamed polyurethane heat insulating material 31 is injected between the outer box 21 and the inner box 20 through the inlet 212a. The injection port 212a is formed in a circular shape or an elliptical shape into which an injection head (not shown) can be inserted and removed. When the injection head is inserted, since the vacuum heat insulating material 30 is already arranged on the flat surface portion 211 of the back wall 21b of the outer box 21 and the flat surface portion 215 of the side wall 21a, the injection port 212a is inserted when the injection head is inserted. The injection head is formed at a position where it does not contact other members, specifically, the inner box 20 or the vacuum heat insulating material 30.

  When the injection head is inserted into the injection port 212a and the foamed polyurethane heat insulating material 31 is injected between the outer box 21 and the inner box 20 from the injection head, foaming is started by a chemical reaction. As a result, the foamed polyurethane 31 expands and grows between the outer box 21 and the inner box 20 or between the vacuum heat insulating material 30 and the inner box 20.

  By the way, as described above, the heat conductivity is lower in the vacuum heat insulating material 30 than in the foam heat insulating material 31, so that the cover rate of the vacuum heat insulating material 30, that is, the contact area between the outer box 21 and the vacuum heat insulating material 30 can be improved. It is most efficient to increase As described above, since the vacuum heat insulating material 30 is bonded and fixed to the flat surface portion 211, the area of the flat surface portion 211 may be increased to increase the size of the vacuum heat insulating material 30. However, in order to increase the area of the flat portion 211 without changing the size of the entire refrigerator 1, the areas of the inclined portion 212 and the jig receiving portion 213a of the mounting portion 213 must be reduced.

  The inclined portion 212 is determined by the size of the injection port 212a, that is, the size of the injection head inserted into and removed from the injection port 212a. Therefore, in this embodiment, the injection port 212a is reduced by using a small injection head (for example, an injection head of less than 30 mm), and the length of the inclined portion 212 in the width direction is shortened accordingly. The area is reduced. Further, the attachment portion 213 affects the adhesive strength between the back wall 21b and the side wall 21a. Therefore, simply shortening the length in the width direction of the jig receiving portion 213a (the length in the left-right direction on the paper surface of FIG. 3) decreases the adhesive strength between the back wall 21b and the side wall 21a. Therefore, in this embodiment, the adhesive strength by shortening the length in the width direction of the jig receiving portion 213a by increasing the length in the width direction of the insertion portion 213b (length in the vertical direction on the paper surface of FIG. 3). Is preventing the decline. That is, by making the length in the width direction of the insertion portion 213b longer than the length in the width direction of the jig receiving portion 213a, sufficient adhesive strength is maintained while reducing the area of the jig receiving portion 213a. .

  By adopting such a configuration, the length of the flat portion 211 in the width direction is increased, the area of the flat portion 211 is increased, and thus the coverage of the vacuum heat insulating material 30 can be increased. In the present embodiment, as described above, the length in the width direction of the flat surface portion 211 is longer, so that the length in the width direction of the flat surface portion 211 is longer than the length in the width direction of the back wall 20b of the inner box 20. long. That is, the vacuum heat insulating material 30 is interposed between the back wall 21b of the outer box 21 and the back wall 20b of the inner box 20 by arranging the width direction of the inner box 20 at a position that is inside the flat portion 211 in the front projection. Can improve heat insulation.

  Further, it is desirable that the polyurethane foam heat insulating material 31 injected between the outer box 21 and the inner box 20 is not brought into contact with the vacuum heat insulating material 30 or the inner box 20 at the time of injection. This is because when the foamed polyurethane heat insulating material 31 adheres to the vacuum heat insulating material 30 or the inner box 20 at the time of injection, the attached foamed polyurethane heat insulating material 31 foams and expands, so that the vacuum heat insulating material 30 and the inner box 20 When the other foamed polyurethane heat insulating material 31 foams and expands, there is a possibility that it cannot flow smoothly and cannot be filled between the outer box 21 and the inner box 20. Because.

  In order to achieve better foaming, in the state of the liquid before the urethane heat insulating material 31 starts to foam, the entire amount is placed in the space formed by the outer box 21 and the inner box 20 of the refrigerator, and the front of the refrigerator is opened. By injecting in the state of being lowered, a uniform urethane heat insulating layer can be formed. For this reason, as described above, urethane insulation adheres in the middle, starts foaming, hinders the spread of the formation process of urethane insulation from below, and decreases the amount of injection into the frontage. It is not preferable for forming a heat insulating layer.

  Therefore, in the present embodiment, an axis extending in the direction perpendicular to the plane portion 211 from the center of the injection port 212a (hereinafter referred to as “axis extending in the direction perpendicular to the plane portion 211 from the center of the injection port 212a”) is referred to as “center of the injection port 212a”. L1 is located on the center line in the lateral direction of the space formed between the vacuum heat insulating material 30 that is bonded and fixed to the flat portion 215 of the side wall 21a of the inner box 20 and the side wall 21a of the outer box 21. The inlet 212a is formed as described above. In other words, the distance from the central axis L1 to the vacuum heat insulating material 30 bonded and fixed to the flat portion 215 of the side wall 21a of the outer box 21 and the distance from the central axis L1 to the side wall 20a of the inner box 20 are substantially the same distance.

By adopting such a configuration, when injecting the polyurethane foam heat insulating material 31, the distance from the tip of the injection head to the side wall 20a of the inner box 20 and the flat part 215 of the side wall 21a of the outer box 21 from the tip of the injection head. The distance to the vacuum heat insulating material 30 that is bonded and fixed can be substantially the same distance. As a result, the foamed polyurethane heat insulating material 31 is disposed approximately in the middle of the vacuum heat insulating material 30 bonded and fixed to the flat portion 215 of the side wall 20a of the inner box 20 and the side wall 21a of the outer box 21. It is possible to minimize adhesion to the vacuum heat insulating material 30 that is bonded and fixed to the flat portion 215 of the side wall 20a of the box 20 and the side wall 21a of the outer box 21.
Further, in the present embodiment, when the foamed polyurethane heat insulating material 31 is injected, the tip of the injection head is located on the front side of the vacuum heat insulating material 30 that is bonded and fixed to the flat portion 211 of the back wall 21b of the outer box 21 (below the paper surface in FIG. 3). Until the position becomes (direction). Thereby, it is possible to prevent the polyurethane foam heat insulating material 31 injected from the injection head from coming into contact with the vacuum heat insulating material 30 bonded and fixed to the flat portion 211 of the back wall 21b of the outer box 21.

  Since the area of the inclined portion 212 is reduced by shortening the length of the inclined portion 212 in the width direction as described above, the inclination angle of the inclined portion 212 with respect to the flat portion 211 becomes steep. In the present embodiment, a lid member 22 that covers the injection port 212 a is provided on the inner surface of the inclined portion 212. The lid member 22 is biased to a position where the inlet 212a is closed by the biasing means 22a and the biasing means 22a attached to the flat surface portion 211 side (the central portion side of the back wall 21b) of the inlet 212a. 22b.

  When injecting the polyurethane foam heat insulating material 31, the injection port 212a is opened by pushing the lid member 22 (lid body 22b) against the urging means 22a toward the inside of the heat insulating box. Then insert the injection nozzle. In the present embodiment, since the inclination angle of the inclined portion 212 with respect to the flat portion 211 is steep as described above, the injection port 212a can be easily opened by moving the lid member 22 a little (by simply pushing). Therefore, it is possible to minimize the deterioration of the adhesion between the biasing means 22a and the inclined portion 212 and the deterioration of the elasticity of the biasing means 22a.

  Returning to FIG. 1 and FIG. 2, in the heat insulating box body as a storage room in order from the top, a refrigerator 3 for storing stored items in a refrigerated state, and a switching means that is juxtaposed to the left and right under the refrigerator 3 and can switch the temperature in the warehouse. Temperature switching room (small freezer room) 4 and ice making room 5, freezer (large freezer room) 6 for storing stored items in a frozen state, vegetable room for storing stored items such as vegetables refrigerated at a higher temperature than the refrigerating room 6 7 is provided. The refrigerator compartment 3 is opened and closed by a double-open door D1 that pivots on one end. The temperature switching chamber 4, the ice making chamber 5, the freezing chamber 6, and the vegetable chamber 7 are opened and closed by drawer type doors D2 to D5 that are formed integrally with a storage case (not shown).

  A first cold air passage 8 and a second cold air passage 9 communicating with each other via a damper are provided on the back of the refrigerator compartment 3, the temperature switching chamber 4, the ice making chamber 5, and the freezer compartment 6. An evaporator 10 and a cold air blower 11 are arranged in the first cold air passage 8, and the discharge ports 8 a, 8 b, 8 c facing the temperature switching chamber 4, the ice making chamber 5 and the freezing chamber 6 (the discharge port 8 b facing the temperature switching chamber 4 is (Not shown) and a return port (not shown) are opened. A discharge port 9 a that faces the refrigerator compartment 3 is opened in the second cold air passage 9. In addition, a communication path (not shown) that connects the refrigerator compartment 3 and the vegetable compartment 7 is provided. A return passage (not shown) for returning cool air to the evaporator 10 is led to the vegetable compartment 7.

  A machine room 12 disposed below the heat insulating box is provided in the lower rear part of the cabinet 2 (behind the vegetable compartment 7). FIG. 4 is a perspective view of the inside of the machine room 12 as viewed from the back. In the machine room 12, a compressor 51, a machine room condenser 52, and a capillary tube 53 that operate a refrigeration cycle are installed. The compressor 51 is connected to a condensing unit including a machine room condenser 52, a capillary tube 53, and an evaporator 10 through a refrigerant pipe through which refrigerant flows, and returns to the compressor 51 to constitute a refrigeration cycle.

  The condensing part constitutes a high temperature part of the refrigeration cycle, and includes a natural convection condensing part that radiates heat by natural convection of ambient air and cools the refrigerant, and a forced convection condensing part that radiates heat by forced convection of ambient air and cools the refrigerant. Have. Thereby, the heat dissipation of a refrigerant | coolant can be enlarged and the coefficient of performance of a refrigerating cycle can be improved. The natural convection condensing part is formed by a heat radiating pipe (not shown) attached to the back surface, side surface or top surface of the cabinet 2. The forced convection condensing part is formed by a machine room condenser 52 arranged in the machine room.

  The refrigeration cycle is operated by driving the compressor 51, and the high-temperature and high-pressure refrigerant compressed by the compressor 51 is condensed while dissipating heat in a condensing unit including a natural convection condensing unit and a forced convection condensing unit (machine room condenser 52). Cool the refrigerant. The high-temperature refrigerant is squeezed by the capillary tube 53 (decompression device), expands to a low temperature and low pressure, and is sent to the evaporator 10. The liquid-phase refrigerant flowing into the evaporator 10 exchanges heat with the air flowing through the first cold air passage 8, evaporates while absorbing heat, and is sent to the compressor 51 as a low-temperature gas refrigerant. Thus, the refrigerant circulates to operate the refrigeration cycle, and cold air is generated by the airflow exchanged with the evaporator 10.

  When the cold air blower 11 is driven, air flows through the first cold air passage 8. At this time, when the damper is opened, cold air flows through the second cold air passage 9. The cold air flowing through the first cold air passage 8 and the second cold air passage 9 is discharged to the refrigerating room 3, the temperature switching room 4, the ice making room 5, and the freezing room 6 through the discharge ports 8a to 8c and 9a, respectively.

  The cold air discharged from the discharge ports 8a to 8c circulates in the temperature switching chamber 4, the ice making chamber 5, and the freezing chamber 6, and the cold air that has taken heat from the temperature switching chamber 4, the ice making chamber 5, and the freezing chamber 6 is the first cold air. Returned to the evaporator 10 in the passage 8. The cold air discharged from the discharge port 9a circulates in the refrigerating chamber 3, and is discharged to the vegetable chamber 7 through the communication path and flows through the vegetable chamber 7. The cold air that has taken heat from the refrigerator compartment 3 and the vegetable compartment 7 is returned to the evaporator 10 in the first cold air passage 8.

  A leg 40 is provided at the front of the lower end of the cabinet 2. A wheel 41 is provided at the rear of the lower end of the cabinet 2. When the front part of the cabinet 2 is lifted, the wheel 41 can roll on the installation surface of the refrigerator 1 to move the refrigerator 1. The wheel 41 is attached to a bottom plate 50 constituting the bottom wall of the machine room 12 as will be described later.

  As shown in FIG. 4, vent holes 12b are opened in both side walls (side plates) 12a of the machine room. Near the center of the machine room 12, a machine room blower 14b comprising an axial fan is disposed. By driving the machine room blower 14b, outside air flows into the machine room 12 through one vent 12b and is exhausted from the other vent 12b. In addition, a vent (not shown) is also opened in the back wall (back plate) 12c of the machine room 12 to promote air circulation in the machine room 12 together with the vent 12b of the side wall 12a.

  A cover member 13 is attached to each of the vent holes 12b. FIG. 5 is a perspective view of the cover member 13. FIG. 6 is a rear view of the cover member 13. FIG. 7 is a side view of the cover member 13. FIG. 7 is a side view of the cover member 13 of FIG. 6 as viewed from the left to the right with respect to the paper surface. The cover member 13 is formed with a plurality of elliptical vent holes 13a. Each of the vent holes 13a is formed with a short vertical width so that it is difficult to insert a finger, and is formed with a long horizontal width so that the air in the machine chamber 12 is efficiently exhausted through the vent holes 13a. .

  A rib 13c protruding outward is formed on the outer surface 13b of the cover member 13. When the rib 13c is in contact with a contact surface of a wall surface, furniture, other electrical appliances, etc., it is between the contact surface and the vent hole 13a. A predetermined gap is formed. As a result, an air flow path is formed between the machine room 12 and the air through the vent hole 13a, so that an air flow is secured. Although the shape of the rib 13c is not particularly limited, in the present embodiment, the cross-sectional shape in front view is formed in a substantially semi-elliptical shape, and the curved portion 13d of the rib 13c is brought into contact with the contact surface when the contact surface and the rib 13c contact each other. The contact surface is prevented from being damaged by the contact.

  A ventilation duct 13f is formed on the inner surface 13e of the cover member 13, and each ventilation hole 13a described above is formed by opening one end of each ventilation duct 13f. The other end of each ventilation duct 13 f opens into the machine room 12. The ventilation duct 13f may be formed to extend in parallel to a direction perpendicular to the opening surface of the ventilation hole 13a, or may be formed to be inclined in the opening direction. It is good also as providing so that the duct length of the ventilation duct 13f distribute | arranged below may become long compared with the duct length of the ventilation duct 13f distribute | arranged upwards. Thereby, the visibility in the machine room 12 from the outside falls. That is, as described above, since the machine room 12 is arranged below the cabinet 2 and on the back side, the user looks down the machine room 12 from above in a normal state. Therefore, by increasing the duct length of the ventilation duct 13f, the visibility in the machine room 12 by the user is lowered in a normal state.

  Although it is good also as extending the duct length of all the ventilation ducts 13f as it goes upwards, air becomes difficult to distribute | circulate by lengthening the duct length 13f, and the air quantity which distribute | circulates the inside of the machine room 12 reduces. . On the other hand, since the lower ventilation duct 13f close to the floor has a small amount of air flowing from the beginning, the duct length of the lower ventilation duct 13f is made longer than the duct length of the upper ventilation duct 13f. As a result, the reduction in the amount of air flowing through the machine chamber 12 can be minimized, and the visibility in the machine room 12 can be reduced.

  The cover member 13 has an engaging claw 13 g at the upper end of the inner surface of the cover member 13. The cover member 13 has engaging claws 13h and 13i at the lower end of the inner surface of the cover member. The engaging claw 13g is formed to have a slight gap between the lower end of the engaging claw 13g and the opening edge of the vent 12b when engaged with the opening edge of the vent 12b. 13 is slidable in the vertical direction with the engaging claw 13g engaged with the opening edge of the vent 12b. As a result, the load applied to the cover member 13 when an impact is applied due to dropping of the refrigerator 1 or the like can be reduced, and the cover member 13 can be prevented from being damaged. The engaging claw 13g has a pressing portion 13j inside thereof, and when the engaging claw 13g engages with the opening edge of the vent hole 12b, the opening claw of the cover member 13 is pressed by pressing the opening edge of the vent hole 12b. Movement in the direction is restricted. As a result, it is possible to prevent the generation of noise, that is, rattling noise, which occurs when the cover member 13 and the opening edge come into contact with each other due to the airflow.

  Further, the cover member 13 has an extending piece 13m extending from the lower rear end to the back wall 12c of the machine room 12. A screw hole 13n is provided in the extended piece 13m. The extending piece 13m is screw-fixed to the back wall 12c of the machine room 12 through a screw hole 13n. Accordingly, the movement of the cover member 13 in the front-rear direction is restricted when the engaging claws 13g, 13h, 13i are engaged with the opening edge of the vent hole 12b.

  A machine room condenser 52 and a compressor 51 are arranged on the right side (left side when viewed from the back) of the machine room blower 14b so as to face the exhaust side of the machine room blower 14b. FIG. 8 is a side sectional view of the bottom plate 50 that forms the bottom wall of the machine room 12. Mounting holes (not shown) are opened at the left and right ends of the rear portion of the bottom plate 50. A wheel 41 whose shaft is pivotally supported by the bottom plate 50 is disposed in the mounting hole.

  The bottom plate 50 is provided with a recess (not shown) whose bottom is closed. A plurality of bosses (not shown) projecting upward are formed in the recess. A hole (not shown) through which a screw is inserted is provided in the boss portion, and the compressor 51 is fixedly disposed on the boss portion by a screw. The rear end corner portion 50a is formed by bending the rear end of the bottom plate 50 upward. The rear end corner portion 50a of the bottom plate 50 has two contact portions that come into contact with the floor surface when the front portion of the cabinet 2 (refrigerator 1) is lifted and the cabinet 2 is tilted. More specifically, the rear end corner part 50a is formed in a stepped shape including a first peak part 50b, a second peak part 50d, and a valley part 50c formed between the peak parts 50b and 50d, and the peak part 50b, 50d becomes a contact part. The second peak portion 50d is located above the first peak portion 50b, that is, on the side farther from the floor surface, and on the rear side than the first peak portion 50b, that is, when the cabinet 2 is tilted. Located on the near side. The peak portions 50b and 50d are formed to have a round shape. By forming the peak portions 50b and 50d to have a round shape, it is possible to prevent the floor surface from being damaged when the floor surface and the peak portions 50b and 50d come into contact with each other.

  Moreover, when the front part of the refrigerator 1 is lifted and brought down, only the first peak part 50b remains on the floor surface until a predetermined angle (second angle described later) after the first peak part 50b comes into contact with the floor surface. The weight of the refrigerator 1 is loaded on the first peak 50b. On the other hand, when it is tilted over a predetermined angle, only the second peak 50d comes into contact with the floor surface, and the weight of the refrigerator 1 is loaded on the second peak 50d. That is, when the refrigerator 1 is tilted, the weight of the refrigerator 1 is not applied to only a single portion of the bottom plate 50, so that the deformation of the bottom plate 50 can be prevented. Moreover, the deformation | transformation of the back wall 12c of the machine room 12 can be prevented by making the weight of the refrigerator 1 loaded to the 2nd peak part 50d small. Hereinafter, the weight of the refrigerator 1 loaded on the second peak portion 50d will be described in detail.

  As described above, the refrigerator 1 is installed with a predetermined gap with respect to the floor surface by the legs 40 and the wheels 41. Therefore, the weight of the refrigerator 1 is loaded at four points of the leg 40 and the wheel 41 that come into contact with the floor surface. Next, when the front part of the refrigerator 1 is lifted, only the wheel 41 is loaded with the weight of the refrigerator. When the refrigerator 1 is further tilted, the first peak 50b and the floor surface come into contact with each other, and the weight of the refrigerator 1 is loaded on the wheel 41 and the first peak 50b. When the refrigerator 1 is further tilted, the weight of the refrigerator 1 is loaded only on the first peak 50b (hereinafter, the tilt of the refrigerator 1 when the weight of the refrigerator 1 begins to be loaded only on the first peak 50b) The angle is also referred to as “first angle”).

  When the refrigerator 1 is further tilted from the first angle, the second peak 50d and the floor surface come into contact with each other, and the weight of the refrigerator 1 is loaded on the first peak 50b and the second peak 50d. , The weight of the refrigerator 1 is loaded only on the second peak 50d (hereinafter, the tilt angle of the refrigerator 1 when the weight of the refrigerator 1 begins to be loaded only on the second peak 50d is expressed as “second Also called “angle”.) However, when the refrigerator 1 is brought down by the user for the purpose of transportation or the like, a part of the weight of the refrigerator 1 is also loaded on the user. In that case, the ratio of the weight of the refrigerator loaded on the 1st peak part 50b or the 2nd peak part 50d, and the weight of the refrigerator 1 loaded on a user is decided according to the inclination angle of the refrigerator 1. FIG.

  The weight of the refrigerator loaded on the first peak portion 50b or the second peak portion 50d is maximized on the center of gravity vertical line of the refrigerator 1 (the vertical line extending from the center of gravity of the refrigerator 1 to the floor surface). The contact point between the peak portion 50b or the second peak portion 50d and the floor surface (hereinafter referred to as the “contact point between the first peak portion 50b or the second peak portion 50d and the floor surface) is simply referred to as the“ contact point ”. Say. ) When there is. On the other hand, when the center of gravity perpendicular line is away from the contact point, the weight of the refrigerator 1 loaded on the user increases, and the weight of the refrigerator 1 loaded on the contact point decreases. Therefore, in the present embodiment, the center of gravity perpendicular to the refrigerator 1 does not pass through the contact point between the second peak 50d and the floor (the point of contact between the second peak 50d and the floor is above the center of gravity perpendicular to the refrigerator 1). To be located).

  In other words, the tilt angle of the refrigerator 1 through which the vertical line of gravity of the refrigerator 1 passes through the second peak 50d is smaller than the second angle described above, and the first peak 50b and the second peak. A portion 50d is formed. With such a configuration, there is a moment when the weight of the refrigerator 1 is almost 100% loaded on the first peak 50b, but the time when the weight of the refrigerator 1 is loaded only on the first peak 50b is Since the weight of the refrigerator 1 is immediately loaded on the second peak 50d, the deformation of the first peak 50b can be minimized. And in the 2nd angle which the 2nd peak part 50d contacts a floor surface, the gravity center perpendicular line of the refrigerator 1 has already moved back rather than the 2nd peak part 50d, and the weight of a refrigerator is in the 2nd peak part 50d. Is not loaded 100%, so that the deformation of the second peak 50d can be minimized.

  Hereinafter, further detailed description will be given with reference to FIGS. 9 and 10. FIG. 9 is a schematic diagram showing reaction force and component force. FIG. 10 is a schematic diagram showing a state in which the second peak and the floor surface are in contact with each other. As described above, the bottom plate (bottom wall) 50 of the machine room 12 may be deformed by the load (weight) from the components such as the compressor 51 mounted on the upper portion and the reaction force applied from the floor via the wheels 41. It is formed so as to have high (strong) strength. On the other hand, the back wall 12c of the machine room 12 has a lower (weaker) strength than the bottom plate 50 because the vent is formed as described above. Therefore, it is desirable to reduce the force applied to the back wall 12c of the machine room 12 when the refrigerator 1 is brought down.

  When the mass of the refrigerator 1 is m, the load F1 applied to the contact point P between the floor surface F and the refrigerator 1 is mg (g = gravity acceleration). Reaction force (so-called floor reaction force) generated at the contact point P is F2 = F1. If the inclination of the refrigerator 1 is θ, the component force F3 applied to the bottom plate 50 of the refrigerator 1 is F1 × sin θ, and the component force F4 applied to the back wall 20c of the machine room 12 is F1 × cos θ. Here, when 0 ≦ θ ≦ π / 2, cos θ decreases as θ increases. Therefore, in order to reduce the component force F4 applied to the back wall 12c of the machine room 12, θ should be brought close to π / 2 (that is, the refrigerator 1 is greatly inclined) and / or the reaction force F2 may be reduced. If the refrigerator 1 is tilted, the angle θ naturally goes to π / 2, but the component force F4 remains large when the tilt angle of the refrigerator 1 is shallow.

  On the other hand, if the reaction force F2 can be reduced, the component force F4 can be reduced whether the tilt angle of the refrigerator 1 is shallow or deep. When the refrigerator 1 is brought down by the user, the reaction force F2 becomes smaller as the contact point P is separated from the center of gravity of the refrigerator 1 as described above. Therefore, in the present embodiment, when the second peak 50d close to the back wall 12c of the machine room 12 and the floor F are in contact, the contact point between the second peak 50d and the floor F is on the vertical line of gravity of the refrigerator 1. The component force applied to the back wall 12c of the machine room 12 is reduced by making it not located at (see FIG. 10).

  In this embodiment, the rear end corner 50a of the bottom plate 50 is formed in a stepped shape including a first peak 50b, a second peak 50d, and a valley 50c formed between the peaks 50b and 50d. However, the shape of the rear end corner portion 50a of the bottom plate 50 is not limited to this. Further, the rear end corner portion 50a of the bottom plate 50 may have three or more contact portions. That is, it is good also as having two or more contact parts which contact a floor surface, when the front part of the cabinet 2 (refrigerator 1) is lifted and the cabinet 2 is inclined.

  Below, it demonstrates in full detail about the cooling cycle of the refrigerator 1 of the said structure. When the refrigeration cycle is operated by driving the compressor 51, the cold air blower 11 and the machine room blower 14b are driven. When the machine room blower 14b is driven, the machine room condenser 52 radiates heat by forced convection, and a heat radiating pipe (not shown) radiates heat by natural convection, and the evaporator 10 absorbs heat to generate cold air.

  Cold air generated by the evaporator 10 flows through the first cold air passage 8 and is discharged from the discharge ports 8 a to 8 c to the temperature switching chamber 4, the ice making chamber 5, and the freezing chamber 6. The cold air discharged to the temperature switching chamber 4, the ice making chamber 5, and the freezing chamber 6 flows through the temperature switching chamber 4, the ice making chamber 5, and the freezing chamber 6, respectively, and flows out from a lower return port (not shown) to be an evaporator. Return to 10. Thereby, the stored matter in the temperature switching chamber 4, the ice making chamber 5, and the freezer compartment 6 is cooled.

  When the damper is opened, cold air flows through the second cold air passage 9 and is discharged from the discharge port 9a to the refrigerator compartment 3. The cold air discharged into the refrigerator compartment 3 circulates in the refrigerator compartment 3 and is discharged into the vegetable compartment 7 through a communication path (not shown). The cold air flowing through the vegetable compartment 7 is returned to the evaporator 10 through the return passage. Thereby, the stored thing in the refrigerator compartment 3 and the vegetable compartment 7 is cooled.

  The present invention can be used for a refrigerator.

DESCRIPTION OF SYMBOLS 1 Refrigerator 2 Cabinet 3 Refrigerating room 4 Temperature switching room 5 Ice making room 6 Freezing room 7 Vegetable room 8 1st cold air passage 9 2nd cold air passage 10 Evaporator 11 Cold air blower 12 Machine room 13 Cover member 14b Machine room blower 20 Inner box 21 Outer box 22 Lid member 30 Vacuum heat insulating material 31 Foam heat insulating material 40 Leg part 41 Wheel 50 Bottom plate 51 Compressor 52 Machine room condenser 53 Capillary tube D1-D5 Door

Claims (5)

A heat insulating box provided on the upper side of the cabinet to form a storage room;
A machine room provided under the cabinet;
In the refrigerator installed on the installation surface with
The refrigerator according to claim 1, wherein the rear end corner portion of the bottom plate constituting the bottom wall of the machine room has a plurality of ridge portions in contact with the installation surface when the cabinet is tilted in the tilt direction.   The refrigerator according to claim 1, wherein the peak portion includes a first peak portion and a second peak portion located on the upper side and the rear side of the first peak portion.   When the cabinet is tilted, the inclination angle of the cabinet where the second peak portion contacts the installation surface is such that the center of gravity line of the cabinet is larger than the inclination angle of the cabinet passing through the second peak portion. The refrigerator according to claim 2, wherein the refrigerator is an angle.   The refrigerator according to any one of claims 1 to 3, wherein the rear end corner portion is formed in a stepped shape.   In the refrigerator of the said structure, the said peak part has a round shape, The refrigerator of any one of Claims 1-4 characterized by the above-mentioned.

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