DE212015000112U1 - fridge - Google Patents

Abstract

A refrigerator (1, 100) in which a front opening of a storage compartment is closed by a left (102) and right (103) double-door door arranged in parallel, the refrigerator (1, 100) comprising: a rotatable one Separating unit (13, 200) provided on an inner surface of at least one of the left (102) and right (103) door in a vertical direction against a pivotally mounted side as a suction surface (111) of a door seal (11, 12, 110) wherein the rotatable separation unit (13, 200) comprises a partition plate (16, 210) forming at least the suction surface (111) of the door seal (11, 12, 110), a thermal insulation material (220) inside the rotatable separation unit (13, 200) is arranged, a separating frame (17, 230), which covers an edge region of the separating plate (16, 210) and an outer surface of the heat insulating material (220), and a heating unit (240), in which a heating element (241) linear on an inner surface of the Trennplat te (16, 210) is arranged, and wherein a connecting element (242) of the heating unit (240) on one of the partition plate (16, 210) opposite side of the thermal insulation material (220) is arranged.

Description

TECHNICAL AREA

The present invention relates to a refrigerator in which a front opening of a storage compartment provided in an upper portion of a housing is closed by left and right double-door-type doors arranged in parallel with each other.

TECHNICAL BACKGROUND

As a large home-use refrigerator, a refrigerator that has many doors for individual storage compartments and diversifies refrigerated storage temperatures according to different user requirements has been put on the market. A top freezer type in which a freezer is disposed in an upper portion of the refrigerator, a middle freezer type in which the freezer is disposed between a refrigerated compartment in an upper area and a vegetable compartment in a lower area, and a lower freezer type; in which a freezer is located in the lowest area, were introduced to the market. There were various forms, for. A type in which a freezing compartment and a vegetable compartment which are elongated in the vertical direction are arranged below a refrigerating compartment which is located in an upper area parallel to each other, and a parallel type in which a freezing compartment and a refrigerating compartment on the left and right sides are arranged parallel to each other, placed on the market.

In such a market environment, in recent years, from the aspect of user-friendliness, a type has been established in which the largest refrigerating compartment of a storage volume which is frequently used and has double-door-type doors is located at the top, an ice-making compartment and a temperature-exchange compartment below the cooling compartment are arranged, the vegetable compartment is arranged below the ice making compartment and temperature change compartment and a freezer compartment in the lowest area. A partition unit, which rotates on closing the door to the other door side, is mounted on an inner surface of the double-door-type door of the refrigerating compartment on an open end side, so that a suction surface of a gasket is formed.

Furthermore, the door in the double-door construction of the refrigerator has been made large in recent years and its dimensions were also elongated in the vertical direction. In order to solve a problem in terms of the exterior design caused by the curvature of the separation unit which is elongated in the vertical direction, a partition plate of the thin steel sheet rotatable separation unit constituting the suction surface of the door seal is designed as follows. That is, the partition plate is formed so that a plate-shaped suction surface and the two end edges, which are folded inwardly, are superimposed, and an angle portion bent further inward is provided. An edge portion of the partition plate and an outer surface of a heat insulating material of the partition plate provided inside the refrigerator are covered with a synthetic resin separator frame, and the separator plate is coupled to and held by the separator frame. Moreover, dew condensation occurring on a surface of the partition plate is suppressed by mounting a surface heater to the inner surface of the partition plate (see, for example, PTL 1).

Hereinafter, the rotary separation unit of the prior art refrigerator will be described with reference to FIG 15 and 16 described.

The rotatable separation unit 13 includes the separation plate 16 made of thin sheet steel, which is a magnetic element that forms a suction surface, a thermal insulation molding 18 from Styrofoam, which forms a thermal barrier coating, and a separating frame 17 made of a synthetic resin, which is an outer shell of the rotary separation unit 13 forms by placing the separator plate 16 and the thermal dam molding 18 covers. In addition, the rotatable separation unit 13 from a surface heating 19 coming from one on an inner surface of the separating plate 16 arranged aluminum foil heating o. Ä. Is formed, and from a cap member 58 located on an upper end portion of the rotatable separation unit 13 is arranged and has an upper end surface on which a guide groove is formed constructed.

In general, in the structure described above, as a measure against leakage current, a grounding wire is needed, which is the separator plate 16 and a housing of the refrigerator 1 connects, as the partition plate 16 , which consists of a thin sheet steel, in direct contact with the surface heating 19 is.

The cap element 58 for the purpose of mounting the rotatable separation unit 13 The refrigerator also serves to connect the separator plate 16 and the separation frame 17 in that its upper end is covered in each case.

However, in the above-described prior art structure, the door seals are 11 and 12 , which are cooled by a temperature influence of the refrigerating compartment, the temperature of which is lowered, in direct contact with the partition plate 16 Made of thin sheet steel, which has a high thermal conductivity. Therefore, a surface temperature of an atmosphere exposed area of the separating plate 16 lowered. There is the problem that not only has a capacity of surface heating 19 is increased more than necessary and the power consumption increases, but also a larger mounting space is required, as on the partition plate 16 Also, a part of an electric wire is arranged with the surface heating 19 connected is.

An object of the invention is to provide a refrigerator in which a power consumption of a heating unit such. B. a radiator or heat conductor of a rotary separation unit o. Ä. Is reduced and also the structure of the rotary separation unit can be simplified.

bibliography

patent literature

• PTL 1: Untested Japanese Patent Publication No. 2010-249491

SUMMARY OF THE INVENTION

A refrigerator according to the invention is constructed such that a front opening of a storage compartment is closed by left and right double-door-type doors arranged in parallel with each other, and an inner surface of at least one of the left and right doors is pivotally supported Suction surface of a door seal, on which a vertically formed rotatable separation unit is provided. Moreover, the rotary separation unit includes a partition plate forming at least the suction surface of the door seal, a heat insulating material disposed inside the rotary separation unit, a separation frame covering an edge portion of the partition plate and an outer surface of the heat insulation material, and a heating unit in which a heating element is arranged linearly on an inner surface of the partition plate. A connecting element of the heating unit is arranged on a side of the thermal insulating material opposite the separating plate.

Therefore, the power consumption of the heating unit for preventing dew condensation on the rotary separation unit can be reduced, a ground wire can be dispensed with, a space in which a magnetic element is disposed inside the separation unit can be ensured, and a simple structure enables cost savings ,

The refrigerator according to the invention is designed to simplify a structure of the rotatable separation unit, to minimize the power consumption for preventing dew condensation and to save energy.

BRIEF DESCRIPTION OF THE DRAWING

1 Fig. 10 is a front view illustrating an opened double-door-type door of a refrigerator in a first embodiment of the invention.

2 Fig. 10 is a sectional view of a main part showing a closed door state of a refrigerating compartment in the first embodiment of the invention.

3 is a sectional view taken along the line 3-3 in 2 ,

4 Fig. 13 is an exploded perspective view of a rotary separation unit of the refrigerating compartment in the first embodiment of the invention.

5A is a side view of an assembly of a thermal insulation material and a heating unit of the cooling compartment in the first embodiment of the invention.

5B is a sectional view taken along the line 5B-5B in 5A ,

5C is an enlarged view of the area C in FIG 5A ,

6 FIG. 12 is a diagram illustrating the relationship between an electrical conductivity of the heating unit and a surface temperature of the partition plate of the refrigerator in the first embodiment of the invention.

7 is a configuration view of a heating unit of a refrigerator in a second embodiment of the invention.

8th Fig. 14 is a view describing the relationship between a heating value of a heating conductor and a surface temperature of a partition plate in each area of the heating conductor of the refrigerator in the second embodiment of the invention.

9 Fig. 10 is a sectional view of a main part showing a closed door state of a refrigerating compartment in a third embodiment of the invention.

10 is a sectional view taken along the line 10-10 in 9 ,

11 Fig. 13 is an exploded perspective view of a rotary separation unit of the refrigerating compartment in the third embodiment of the invention.

12 is a specific structural view of a heating unit of the refrigerator in the third embodiment of the invention.

13 Fig. 13 is an exploded perspective view of a rotary separation unit of a refrigerating compartment in a fourth embodiment of the invention.

14 is a specific structural view of a heating unit of the refrigerator in the fourth embodiment of the invention.

15 Fig. 10 is a sectional view illustrating a closed door state of a refrigerator compartment of a refrigerator of the prior art.

16 Fig. 11 is an exploded perspective view of a rotary separation unit of the prior art refrigerator.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the invention will be described with reference to the drawings. The invention is not limited to these embodiments.

FIRST EXAMPLE EMBODIMENT

1 Fig. 10 is a front view illustrating an opened double-door-type door of a refrigerator in a first embodiment of the invention. 2 Fig. 10 is a sectional view of a main part showing a closed door state of a refrigerating compartment in the first embodiment of the invention. 3 is a sectional view taken along the line 3-3 in 2 , 4 Fig. 13 is an exploded perspective view of a rotary separation unit of the refrigerating compartment in the first embodiment of the invention. 5A is a side view of an assembly of a thermal insulation material and a heating unit of the cooling compartment in the first embodiment of the invention. 5B is a sectional view taken along the line 5B-5B in 5A , 5C is an enlarged view of the area C in FIG 5A , 6 FIG. 12 is a diagram illustrating the relationship between an electrical conductivity of the heating unit and a surface temperature of the partition plate of the refrigerator in the first embodiment of the invention.

In 1 owns the fridge 100 a left door 102 , arranged on a left side, and a right door 103 , arranged on a right side. 1 shows a state in which the left door 102 and the right door 103 are open. An area where the left door 102 and right door 103 are provided, is an area of the refrigerator compartment 105 , The ice making compartment 106 is below the left door 102 arranged and the freezer 107 and the vegetable compartment 108 are still below. The exchange compartment 109 is below the right door 103 and on a right side of the ice making tray 106 arranged.

The left door 102 and the right door 103 are each pivotally mounted by hinge areas, so that they are open to the left or to the right side. The rotatable separation unit 200 is opposite the pivotally mounted side on the left door 102 intended. The rotatable separation unit 200 rotates according to the opening and closing operations of the left door 102 wherein the sides of the left door opposite the pivotally mounted sides 102 and right door 103 with the door closed through the door seals 110 are closed, allowing the escape of cold air from the inside of the refrigerator compartment 105 is prevented.

Here, a heat-insulating partition (not shown) is arranged in each storage compartment. Sheet steel covers 501 . 502 and 503 are arranged on a front surface of the heat-insulating partition member and are closed by the door seal of the respective storage compartment door. Thus, the escape of cold air from each storage compartment is prevented.

As in 2 to 5 shown, has the rotatable separation unit 200 over a partition plate 210 which is a suction surface 111 the door seal 110 forms, as well as a thermal insulation material 220 inside the rotatable separating unit 200 is arranged and made of styrofoam. In addition, there is the rotatable separation unit 200 from a synthetic resin separating frame 230 , the one edge area of the separating plate 210 and an outer surface of the thermal insulation material 220 covering, and a heating unit 240 that comes from a heating element 241 placed in a center of an inner surface of the separating plate 210 is arranged, and a connecting element 242 is constructed. In addition, for example, the reinforcing plate 250 from a metal plate with a low coefficient of thermal expansion between the thermal insulation material 220 and the separation frame 230 essentially over the entire range of the height of the rotatable separation unit 200 arranged in a height direction of the refrigerator.

Here is the partition plate 210 made of a synthetic resin and two magnetic elements 211 are arranged on their inner surface. The magnetic elements 211 are essentially over the entire range of height of the rotary separation unit 200 arranged in the height direction of the refrigerator. Furthermore, the magnetic elements 211 arranged so that they are in a state in which the left door 102 and the right door 103 are closed, the magnetic bodies 112 face each other inside the door seal 110 are arranged. In this embodiment, as a magnetic element 211 a rectangular plastic magnet used. Furthermore, the heating element 241 the heating unit 240 and the magnetic elements 211 between the partition plate 210 and the thermal insulation material 220 kept in a pressed state. In addition, the heating element has 241 the heating unit 240 a linear shape formed of a linear heating conductor, and is between the magnetic elements 211 parallel to the magnetic elements 211 arranged. Furthermore, it is the connecting element 242 the heating unit 240 around a low resistance electrical wire that generates no heat and is located on a surface opposite the heater element 241 in pressure contact with the thermal insulation material 220 and dividing frame 230 located.

Next, an overall construction of the rotary separation unit will be described 200 with reference to the exploded perspective view of 4 and an arrangement of the heating unit 240 with reference to the assemblies in the 5A to 5C described. The rotatable separation unit 200 includes a separator plate 210 , which consists of synthetic resin and a suction surface 111 the door seal 110 forms, as well as a thermal insulation material 220 made of styrofoam, inside the rotatable separating unit 200 is arranged. In addition, the rotatable separation unit includes 200 a reinforcing plate 250 from the metal plate and the separating frame 230 , which consists of the synthetic resin and the edge area of the partition plate 210 and the outer surface of the thermal insulation material 220 covers. The rotatable separation unit 200 further includes the heating unit 240 coming from the heating element 241 on one side of the separator plate 210 of the thermal insulation material 220 is arranged, and a connecting element 242 on one side of the reinforcing plate 250 is arranged, is constructed. In addition, two magnetic elements 211 between the heating element 241 , which is in the middle of the inner surface of the separating plate 210 is arranged, and the inner surface of the partition plate 210 mounted so that the heating element 241 is clamped. Furthermore, the heating unit 240 in a heating element 241 , which is a heating conductor, and a connecting element 242 , which is an electrical wire in the lowest part of the thermal insulation material 220 acts, split.

Hereinafter, an operation of the above-described refrigerator will be explained.

First, in the above-described prior art arrangement, those disclosed in U.S. Pat 15 is shown, the door seals 11 and 12 caused by the temperature influence of the cooling compartment 3 , whose temperature is lowered, cooled, in direct contact with the partition plate 16 made of thin steel sheet with high thermal conductivity, which reduces the surface temperature of the exposed area of the separator plate 16 is reduced more than necessary. To the lowered surface temperature of the separating plate 16 then raise to or above a dew point temperature, it is necessary to increase the performance of surface heating 19 to increase. In contrast, in the case of this embodiment, the partition plate 210 the rotatable separation unit 200 which the suction surface 111 the door seal 110 forms, from the synthetic resin.

Here, with the same electrical conductivity, the surface temperature of the separator plate 210 in the case of this embodiment, about 3K higher than the surface temperature of the partition plate 16 from the prior art, as in the diagram of the relationship of the electrical conductivity of the heating unit 240 and the surface temperature of the separator plate of 6 shown. Furthermore, it can be seen that the electrical conductivity is reduced by about 10% to maintain the dew point temperature in outdoor air conditions of 30 ° C and 75%. The reason is that the separator plate 210 with which the door seal 110 is made of the resin of low thermal conductivity, so that a reduction in the temperature of the atmosphere exposed area 212 the partition plate 210 is suppressed.

In addition, the magnetic elements 211 arranged so that they are the magnetic elements 112 face each other inside the door seal 110 are arranged. Thus, a function of tight suction on door seal 110 , which is a basic function of the rotary separation unit 200 be guaranteed.

In the case of the partition plate 210 and the separation frame 230 Made of synthetic resin, the elements are also influenced by the thermal expansion. For example, if the temperature inside the refrigerator is low, the separator will stretch 230 together, and when the temperature outside the refrigerator is high, the partition plate expands 210 out. Therefore, due to the different expansion and contraction on one longitudinal side, a distortion force acts on the rotatable separation unit 200 one. The reinforcement plate 250 However, metal essentially becomes over the entire range of the height of the rotary separation unit 200 plugged in, which makes it possible to eliminate the influence of warping.

As described above, in this embodiment, on the inner surface of at least one of the left and right doors (here, the left door 102 ) of the refrigerating compartment 105 opposite the pivotally mounted side, the rotatable separation unit 200 arranged over the entire range of height in the vertical direction. In addition, it is the suction surface 111 the door seal 110 around the partition plate 210 made of synthetic resin and magnetic elements 211 are inside the partition plate 210 arranged so that they are the magnetic elements 112 face the inside of the door seal 110 are integrated. The heating element 241 the heating unit 240 is linear between the magnetic elements 211 arranged so that it is parallel to these, and the separation frame 230 , which consists of synthetic resin, covers the edge area of the partition plate 210 and the outer surface of the thermal insulation material 220 , Due to the structure, the surface temperature of the separation plate can be 210 be kept at a higher level than those of the thin steel sheet of the prior art and the power consumption of the heating unit 240 to prevent dew condensation is reduced. Therefore, it is possible to reduce the power consumption of the refrigerator 100 to reduce.

In addition, the connecting element 242 the heating unit 240 at a heating element 241 opposite side of the thermal insulation material 220 arranged. According to the structure, the heating element 241 arranged linearly, a mounting space for the magnetic elements 211 attached to the inner surface of the separating plate 210 can be arranged, and the magnetic elements 211 can the magnetic elements 112 on the inner surface of the door seal 110 exactly opposite. As a result, it is possible to ensure the reliability of a suction state between the rotary separation unit 200 and the door seal 110 to ensure.

Because the heating unit continues 240 on the inner surface of the separating plate 210 is made of synthetic resin, an area touched by a person is made of synthetic resin, whereby it becomes unnecessary to measure the leakage current and the cost can be reduced by omitting the grounding wire.

In addition, the reinforcing plate 250 made of metal, substantially over the entire range of height between the thermal insulation material 220 and the separation frame 230 plugged in. Therefore, it is possible to prevent the rotatable separation unit 200 due to the different thermal expansion of the separating plate 210 made of synthetic resin and the separating frame 230 warps, and it can ensure a highly reliable door seal, which prevents the ingress of heat from the outside.

SECOND EXEMPLARY EMBODIMENT

7 is a specific structural view of a heating unit of a refrigerator in a second embodiment of the invention and 8th Fig. 14 is a view describing the relationship between a heating value of a heating conductor and a surface temperature of a partition plate in each area of the heating conductor of the refrigerator in the second embodiment of the invention. The same reference numerals are used for the same structures as in the first embodiment of the invention, and various portions will be described.

In 7 is the heating unit 240 from a heating element 241 in the form of a linear heating conductor with a length L on a right side and a connecting element 242 in the form of an electric wire or the like which generates no heat, built on a left side of an alternate dashed and dotted line. As in 4 of the first embodiment is the heating element 241 in the middle of the partition plate 210 of synthetic resin substantially at the same height as the rotatable separation unit arranged substantially over the entire height range 200 arranged. The heating value, that is, the power density of the heating element 241 , is variable, and in 7 three areas - area a, area b and area c - are shown, which have different heating values. In addition, a special unit that ensures that the heating element of the heating element 241 is variable by varying a resistance value by changing a winding wire pitch of a linearly wound resistance wire by making a resistance paste component of a printed resistor variable for setting as sheet resistance or by connecting heat generating resistance wires having different resistance values in series. Further, although the area is divided into three areas in this embodiment, the number of divisions may be changed as needed.

For the refrigerator constructed as described above, the operation will be described below with reference to FIG 8th explained.

First, the surface temperature of the separation plate 210 in a case where no electric current flows through the heating conductor (current flow through heating conductor: No), as indicated by the dotted line, low in a middle region (region b) and rising toward the ends (region a and region c) , The reason for this is that due to a sealing property and the thermal conductivity between the cooling compartment 105 and the door seal 110 or by a cold air circulating effect inside the refrigerating compartment 105 an unevenness of Temperature distribution is effected. In a case of the current flowing through the heating conductor (current flow through heating conductor: yes), it is now due to the fact that the surface temperature of the partition plate 210 is in a dew condensation area, it is necessary to pass electric current through the heating conductor and raise the temperature of each area to a dew condensation limit line or higher.

In this case, in the prior art heating conductor in which the heating value indicated by an alternate dotted and dashed line is constant, due to the constant temperature rise in each region, the heating value in the region b is the temperature thereof is lowest, and an unnecessary temperature increase with respect to area a and area c is generated as indicated by an alternate dotted and dashed line.

In contrast, the heating value of the heating conductor in this embodiment is as in FIG 7 shown variable between the areas. That is, the heating value is large in the region b, and the heating values of the region a and region c are small as indicated by a solid line. Therefore, the surface temperature (dashed line) of the partition plate 210 when no electric current flows through the heating conductor, the uniform surface temperature (solid line) that exceeds the dew point limit line by the minimum required temperature correspond. Compared with the heating value of the prior art heat conductor, a heating value of an area surrounded by oblique lines is not needed, so that the power consumption can be reduced accordingly.

As described above, the heating element is 241 the heating unit 240 in this embodiment, by an area divided into a plurality of areas, the power density of the individual areas being variable. Therefore, a uniform surface temperature of the separation plate 210 achieved even if the heat insulating ability due to deformation of the rotary separation unit 200 of the refrigerator 100 is impaired, so that no variation of the temperature distribution occurs and unnecessary power consumption can be avoided.

THIRD EXAMPLE EMBODIMENT

9 Fig. 10 is a sectional view of a main part illustrating a closed door state of a refrigerating compartment in a third embodiment of the invention; and Figs 10 is a sectional view taken along the line 10-10 in 9 , Furthermore is 11 an exploded perspective view of a rotary separation unit of the cooling compartment in the third embodiment of the invention and 12 is a specific structural view of a heating unit of the refrigerator in the third embodiment of the invention. Moreover, the same reference numerals are used for the same structures as in the first embodiment and the second embodiment of the invention and various portions will be described.

In 9 to 12 is the heating element 241 the heating unit 240 between two magnetic elements 211 that are linear in the separator plate 210 are arranged, arranged, and two (reciprocal) heating elements 241 are arranged parallel to each other and are covered by the thermal insulation material 220 in which they are pressed, kept to not with the magnetic elements 211 to get in touch. In addition, in this embodiment, although two heating elements 241 between the magnetic elements 211 However, their number can be increased as long as there is enough space available.

Furthermore, there are the change or switching areas 243 connecting an electrical connection between the heating element 241 from a heating conductor with the connecting element 242 made of an electric wire, in a portion of the area a in the heating unit 240 , The change or switching range 243 requires watertightness, and generally resin or pipe sealed over molding is used so that the switching range 243 thicker than the linear heating element 241 is. Therefore, the number of heating elements 241 that run parallel in a lateral direction, less than their number in the other areas b and c.

For the refrigerator constructed as described above, the operation will be explained below.

As described in the first embodiment and the second embodiment, the power density of the heating conductor of the heating element 241 initially variable in a similar way so that the in 8th shown surface temperature of the separating plate 210 can be achieved, which is constant over the entire length L. As in this embodiment, a plurality of heating elements 241 are arranged, it is possible to achieve a desired temperature increase with lower power consumption than in the first embodiment and the second embodiment.

The change or switching ranges 243 are located in area a, the number of heating elements 241 is less than in region c and the heating power is insufficient in the heating conductor with the same power density as that of region c. There the number of heating wires in area c is two, while the number of heating wires of area a is one, it is now possible to achieve the same temperature increase when the power density of area a is twice that of area c.

Although in this embodiment the power density for region a is increased, the power density for any range where the number of the heating conductors of the heater elements can be further increased 241 is lower than in the other areas, increased.

As described above, in this embodiment, a plurality of heating elements 241 the heating unit 240 linear between the magnetic elements 211 inside the separator plate 210 arranged. Therefore, their arrangement can be made in a narrow space, the power density per unit length of the heating conductor of the heating element 241 is low or the electrical conductivity can be reduced. Therefore, it is possible to reduce the power consumption for preventing the dew condensation. Furthermore, the heating unit 240 only on one surface of the thermal insulation material 220 intended. Consequently, it is also possible to simplify the wiring operation and reduce the required man-hours.

In addition, the power density between each area, affecting a variety of heating elements 241 the heating unit 240 are divided, variable, and the power density of a portion of the heating elements 241 parallel to the alternating or switching ranges 243 is greater than the power densities of other sections. According to the construction, a lower temperature rise due to the smaller number of heating elements 241 near the change or switching ranges 243 balanced, it becomes a uniform surface temperature of the partition plate 210 the rotatable separation unit 200 achieved, there is no variation of the temperature distribution and the power consumption can be further reduced.

FOURTH EXEMPLARY EMBODIMENT

13 is an exploded perspective view of a rotary separation unit of a refrigerating compartment in a fourth embodiment of the invention and 14 is a specific structural view of a heating unit of a refrigerator in the fourth embodiment of the invention. The same reference numerals are used for the same structures as in the first to third embodiments, and various portions will be described.

In 13 and 14 are the change or switching ranges 243 ( 243a and 243b ), the connecting element (electric wire) 242 , which produces an electrical connection, as well as the heating element (heating conductor) 241 the heating unit 240 in a longitudinal direction near a center of the rotary separation unit 200 arranged. The region d having a length L1 and power density W1 is one with the one switching range 243a on one side of the connector 242 and the region j having the same length L1 and the same power density W1 is connected to the other change or switching range 243b connected. Further, the region e having the length L2 and the power density W2 and the region f having the length L3 and the power density W3 are connected to the region d in this order. Further, the region i having the length L2 and the power density W2 and the region h having the length L3 and the power density W3 are connected to the region j in this order. The region g of length L4 and power density W4 is connected to region f and region h, forming a closed variable power density heating conductor loop. Further, although the heat-generating regions in this embodiment are seven regions from region d to region j, any number of regions, their power densities and lengths may be symmetrical with respect to the switching region 243a and the change or shift range 243b are to be provided.

In addition, since the area g of the heating element 241 , the parallel next to the change or switching range 243a and change or switching range 243b runs, has a smaller number than the other areas, the power density can be increased. That is, there is a general relationship W4> (W1 to W3).

For the refrigerator constructed as described above, the operation will be explained below.

When electricity goes through the heating unit 240 flows, generates each of the areas d to j of the heating element 241 Heat and a surface of the separating plate 210 is stabilized over the entire length L at a desired temperature.

If it comes to manufacturing errors and the change or switching range 243a and the change or shift range 243b Inversely, the following problems may occur. That is, the correct order of the heat generating areas of the heating element 241 Range d range e range f range g range h range i range j becomes the wrong order range j range i range h range g range f range e range d. Continue in a case where the power densities and lengths differ from region d to region j, the variation of the surface temperature of the separation plate 210 amplified and results in a non-uniform temperature distribution when the change or switching range 243a and the change or shift range 243b be arranged vice versa.

In this embodiment, however, the relationship between the power density and the length changes along the entire length L of the heater element 241 even if the change or shift range 243a and the change or shift range 243b be arranged inversely, in no way compared to the case of regular assembly, as there is vertical symmetry.

As described above, in this embodiment, the power density and the length of the area d of the one switching area agree 243a connected heating element with the range j of the other change or switching range 243b connected heating element match. Furthermore, in an analogous manner, the power densities and the lengths of region e and region i of the heater element, each associated with varied power density in order, are coincident with each other. That is, in the heating unit 240 whose heat generation distribution is symmetrical with respect to the switching area 243a and the change or shift range 243b is, are the change or switching range 243a and the change or shift range 243b in the longitudinal direction in a center of the rotary separation unit 200 arranged. According to this construction, the relationship between the power density and the length of the heater element 241 which are varied, vertically symmetrical and the surface temperatures of the separator plate 210 the rotatable separation unit 200 even if during assembly of the heating unit 240 when assembling the rotatable separation unit 200 the change or switching range 243a and the change or shift range 243b be attached in reverse. Therefore, no assembly error occurs in one step and the labor hours necessary to control the orientation of the heating unit 240 and for mounting the heating unit 240 can be significantly reduced.

As described above, in the invention, the front opening of the storage compartment is closed by the left and right double-door-type doors arranged parallel to each other, and the inner surface of at least one of the left and right doors opposite to a pivotally mounted side constitutes the suction surface of the Door seal is where the formed in the vertical direction rotatable separation unit is provided. Moreover, the rotary partition unit includes the partition plate that forms at least the suction surface of the door seal, the heat insulating material disposed inside the rotary separation unit, the partition frame that covers the edge portion of the partition plate and the outer surface of the heat insulating material, and the heater unit in which the heating element is arranged linearly on the inner surface of the partition plate. Moreover, the connecting element of the heating unit is arranged on the side of the thermal insulation material opposite the separating plate.

According to the configuration, since only the heater element of the heater unit is arranged linearly, a structure may be provided in which the magnetic elements are disposed inside the separator plate, and it is possible to increase the dew condensation on the surface of the separator plate of the rotary separator with minimum power consumption prevention.

In the invention, the heating element of the heating unit may be divided into the plurality of separate heating elements, and the power density of the individual separate heating elements may be variable.

According to the structure, no variation in temperature distribution occurs, and unnecessary power consumption can be avoided because the surface temperature of the separator plate of the rotary separator is uniform.

Moreover, in the invention, the reinforcing plate may be disposed between the heat insulating material and the separating frame.

According to the structure, the distortion of the rotary separation unit can be prevented due to the temperature difference between the inside and the outside of the compartment of the refrigerator, and it is possible to suppress the penetration of heat from the outside into the inside of the compartment.

Moreover, in the present invention, the front opening of the storage compartment is closed by the left and right double-door-type doors arranged parallel to each other, and the inner surface of at least one of the left and right doors opposite to a pivotally mounted side constitutes the suction surface of the door seal on which the vertically-formed rotatable separation unit is provided. In addition, the rotary separation unit includes the partition plate that forms at least the suction surface of the door seal, the thermal insulation material disposed inside the rotary separation unit, the separation frame that covers the edge portion of the separation plate and the outer surface of the heat insulation material, the magnetic elements that are linear are arranged at the door seal opposite positions on the inner surface of the partition plate, and the heating unit for heating the inner surface of the partition plate. In addition, the plurality of heating elements of the heating unit can be arranged linearly between the magnetic elements.

According to the constitution, there can be provided a structure in which the heating unit is arranged in a narrow space of the entire vertical length of the partition plate, and it is possible to prevent the dew condensation on the surface of the partition plate of the rotary separation unit with minimum power consumption.

Moreover, in the invention, the heating element of the heating unit is divided into the plurality of separate heating elements, and the power density of each is variable. Moreover, the changeover range for electrically connecting the heater element of the heater unit and the connector between the heater element and the connector may be provided, and the power density in the portion of the heater element that is parallel to the changeover range may be greater than the power densities in other portions.

According to the structure, no variation in temperature distribution occurs, and unnecessary power consumption can be avoided because the surface temperature of the separator plate of the rotary separator is uniform.

Moreover, in the invention, the changing portion for electrically connecting the heating element of the heating unit and the connecting member may be provided therebetween, and the changing portion may be arranged longitudinally in the center of the rotary separating unit.

According to the construction, a restriction of the mounting direction upon insertion of the heating unit during assembly of the rotary separation unit is eliminated and quality improvements are made possible.

Moreover, in the invention, the heating element of the heating unit may be divided into the plurality of separate heating elements, the power density of the individual separate heating elements may be variable, and the heating unit may cause the heat generation distribution in the longitudinal direction of the rotary separating unit to be symmetrical with respect to the changing area.

According to the constitution, it is possible to achieve an approximation of the surface temperature of the separation plate and improve the assembling quality.

In addition, the partition plate and the separation frame in the invention may be formed of a synthetic resin.

According to the structure, the heat transfer between the inside of the compartment and the outside of the compartment can be reduced, and it is possible to suppress the dew condensation on the surface of the partition plate of the rotary separation unit with minimum power consumption.

INDUSTRIAL APPLICABILITY

As described above, the refrigerator according to the invention can prevent the dew condensation of the surface of the separator plate of the rotary separator unit with minimum power consumption, thereby making it suitable as a domestic refrigerator as well as a commercial refrigerator.

LIST OF REFERENCE NUMBERS

1, 100

fridge

11, 12, 110

door seal

13, 200

rotatable separation unit

16, 210

separating plate

17, 230

separating frame

102

left door

103

right door

105

refrigerated compartment

106

Eisbereitungsfach

107

freezer

108

crisper

109

exchange trade

111

suction

112

magnetic element

211

magnetic element

212

the atmosphere exposed area

220

thermal insulation

240

Heating unit

241

Heating element

242

Connecting element (electric wire)

243, 243a, 243b

change region

250

reinforcing plate

501, 502, 503

cover

Claims (9)

Fridge ( 1 . 100 ), in which a front opening of a storage compartment is replaced by a left ( 102 ) and right ( 103 ) Door in double-door design, which are arranged in parallel, is closed, with the refrigerator ( 1 . 100 ) includes: a rotatable separation unit ( 13 . 200 ) located on an inner surface of at least one of the left ( 102 ) and right ( 103 ) Door in a vertical direction opposite a pivotally mounted side as a suction surface ( 111 ) a door seal ( 11 . 12 . 110 ), wherein the rotatable separation unit ( 13 . 200 ) a separating plate ( 16 . 210 ), which at least the suction surface ( 111 ) of the door seal ( 11 . 12 . 110 ), a thermal insulation material ( 220 ) inside the rotatable separation unit ( 13 . 200 ), a separating frame ( 17 . 230 ), one edge region of the separating plate ( 16 . 210 ) and an outer surface of the thermal insulation material ( 220 ), as well as a heating unit ( 240 ), in which a heating element ( 241 ) linearly on an inner surface of the separating plate ( 16 . 210 ) is arranged, and wherein a connecting element ( 242 ) of the heating unit ( 240 ) on one of the separating plate ( 16 . 210 ) opposite side of the thermal insulation material ( 220 ) is arranged. Fridge ( 1 . 100 ) according to claim 1, wherein the heating element ( 241 ) of the heating unit ( 240 ) in a plurality of separate heating elements ( 241 ) and a power density of the individual separate heating elements ( 241 ) is variable. Fridge ( 1 . 100 ) according to claim 1 or 2, further comprising: a reinforcing plate ( 250 ) between the thermal insulation material ( 220 ) and the separation frame ( 17 . 230 ) is arranged. Fridge ( 1 . 100 ) according to claim 1, wherein the separating plate ( 16 . 210 ) and the separating frame ( 17 . 230 ) are made of a synthetic resin. Fridge ( 1 . 100 ), in which a front opening of a storage compartment is replaced by a left ( 102 ) and right ( 103 ) Door in double-door design, which are arranged in parallel, is closed, with the refrigerator ( 1 . 100 ) includes: a rotatable separation unit ( 13 . 200 ) located on an inner surface of at least one of the left ( 102 ) and right ( 103 ) Door in a vertical direction on the side opposite a pivotally mounted side of at least one of the left ( 102 ) and right ( 103 ) Door as suction surface ( 111 ) a door seal ( 11 . 12 . 110 ), wherein the rotatable separation unit ( 13 . 200 ) a separating plate ( 16 . 210 ), which at least the suction surface ( 111 ) of the door seal ( 11 . 12 . 110 ), a thermal insulation material ( 220 ) inside the rotatable separation unit ( 13 . 200 ), a separating frame ( 17 . 230 ), one edge region of the separating plate ( 16 . 210 ) and an outer surface of the thermal insulation material ( 220 ), magnetic elements ( 112 ; 211 ), which are linear on the door seal ( 11 . 12 . 110 ) opposed positions on an inner surface of the partition plate ( 16 . 210 ) are arranged, as well as a heating unit ( 240 ) for heating the inner surface of the separating plate ( 16 . 210 ), and wherein a plurality of heating elements ( 241 ) of the heating unit ( 240 ) linear between the magnetic elements ( 112 ; 211 ) is arranged. Fridge ( 1 . 100 ) according to claim 5, wherein the individual heating elements ( 241 ) of the heating unit ( 240 ) in a plurality of separate heating elements ( 241 ), a power density of the individual separate heating elements ( 241 ) is variable, a change range ( 243 . 243a . 243b ) for the electrical connection of the heating element ( 241 ) of the heating unit ( 240 ) and the connecting element ( 242 ) between the heating element ( 241 ) and the connecting element ( 242 ) is provided and a power density of a portion of the heating element ( 241 ), which is parallel to the changeover area ( 243 . 243a . 243b ) is greater than the power densities in other sections. Fridge ( 1 . 100 ) according to claim 5 or 6, wherein the change region ( 243 . 243a . 243b ) for the electrical connection of the heating element ( 241 ) of the heating unit ( 240 ) and the connecting element ( 242 ) between the heating element ( 241 ) and the connecting element ( 242 ) and the change area ( 243 . 243a . 243b ) in the longitudinal direction in a center of the rotary separation unit ( 13 . 200 ) is arranged. Fridge ( 1 . 100 ) according to claim 7, wherein the heating element ( 241 ) of the heating unit ( 240 ) in the plurality of separate heating elements ( 241 ), the power density of the individual separate heating elements ( 241 ) is variable and the heating unit ( 240 ) causes the heat generation distribution in the longitudinal direction of the rotary separation unit ( 13 . 200 ) symmetric with respect to the changeover area ( 243 . 243a . 243b ). Fridge ( 1 . 100 ) according to claim 5, wherein the separating plate ( 16 . 210 ) and the separating frame ( 17 . 230 ) are made of a synthetic resin.

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