JP2012047345A - Refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigerator in which opening and closing action are smooth even if large-sized, and includes a reduced pressure storage compartment in which the cleaning of the interior is easy.SOLUTION: The refrigerator includes a storage compartment consisting of a first contour member having a first opening and a second opening and a second contour member closing the second opening, and a lid member which opens and closes the first opening, wherein the opening edge of the second opening of the first contour member is formed to slope back from the first opening, the under surface of the storage compartment is of a curved shape convexed downward, and a first concave portion concaved from the inner surface to the outer surface is provided near the center of the under surface.

Description

The present invention relates to a refrigerator.

  The refrigerator described in Patent Document 1 is provided with an outer shell member and a lid member made by integral molding that constitute a decompression storage chamber, and a food tray is pulled out together with a lid member that opens and closes the opening of the outer shell member.

  The refrigerator described in Patent Document 2 discloses a configuration in which an upper surface of a decompression chamber is reinforced with tempered glass and a lower surface is reinforced with an iron plate. The decompression chamber lid is configured to reciprocate back and forth supported by guide rails provided on the left and right outer sides of the decompression chamber, and includes rack gears provided on the guide rails and left and right pinion gears engaged with the rack gears. Yes.

Japanese Patent No. 4324635 JP 2009-036453 A

  Here, if the decompression storage chamber is enlarged, that is, if the width can be increased to increase the internal volume, various foods can be easily stored, and the convenience for the user is improved. However, if the configuration described in Patent Document 1 and Patent Document 2 is simply increased in size, there is a risk that the structure cannot be stored under reduced pressure.

  Specifically, Patent Document 1 has a configuration without synchronization means (for example, a rack and pinion gear) that prevents the lid member from tilting left and right. In this configuration, when the width of the outer member is increased, the lid member tends to tilt left and right during the opening and closing operation.

  Further, the outer member is integrally formed of resin. That is, the inner wall is molded by pulling the mold toward the opening. For this reason, it is difficult to provide a component or the like inside the outer member or to form a complicated uneven shape.

  Next, when the width is increased in the configuration of Patent Document 2, both the tempered glass and the iron plate are enlarged and the mass is increased. In addition, the cost increases and it is not suitable for mass production of household refrigerators. For example, in the configuration of Patent Document 2, in the case of a decompression chamber having a width of about 400 mm, the weight is about 7 kg. If the width is expanded 1.5 times, it will be about 10kg.

  Further, Patent Document 1 and Patent Document 2 do not describe water droplets condensed on the inside of the wall surface of the decompression chamber, or the effects and cleaning properties when liquid foreign matter is spilled inside the decompression chamber.

  Therefore, an object of the present invention is to provide a refrigerator including a decompression storage chamber that can be smoothly opened and closed even when the size is increased, and the inside can be easily cleaned.

  In order to solve the above problems, for example, the configuration described in the claims is adopted. The present application includes a plurality of means for solving the above-mentioned problems. For example, in a refrigerator having a storage space, the storage space includes a box-shaped storage container, and the storage container stores stored items. A first opening to be taken in and out; a lid member for opening and closing the first opening; and the lid member and the first opening provided between the lid member and the first opening in contact with the lid member A seal member that suppresses gas movement between the upper surface, the lower surface, the left and right side surfaces, and a rear surface opposite to the first opening, and a second outer opening formed on the upper surface And a second outer member that closes the second opening, and the lower surface of the first outer member has a curved shape that protrudes downward, and from the inner surface than the center of the lower surface. It is characterized in that a first recess is provided on the outer surface.

  ADVANTAGE OF THE INVENTION According to this invention, even if it enlarges, the opening / closing operation | movement is smooth and the refrigerator provided with the decompression storage chamber which an internal cleaning is easy can be provided.

It is the figure which looked at the refrigerator main body in embodiment of this invention from the front. FIG. 2 is a conceptual cross-sectional view taken along line AA in FIG. 1. It is the BB sectional view taken on the line of FIG. It is the BB sectional drawing of FIG. 1, and shows the state which opened both the refrigerator compartment door and the decompression chamber door. It is the perspective view which looked at the structure of the decompression chamber from diagonally forward upper direction. It is the simple perspective exploded view which looked at the outline member from the front upper part. It is the front view seen from the C direction of FIG. It is the KK sectional view taken on the line of FIG. It is the JJ sectional view taken on the line of FIG. It is the arrow line view which looked at FIG. 5 from the C direction. It is the DD sectional view taken on the line of FIG. It is the FF sectional view taken on the line of FIG. It is the EE sectional view taken on the line of FIG. It is the perspective view seen from the A direction of FIG. 5 which shows the structure of a cover member and a food tray. It is the perspective view seen from the B direction of FIG. 5 which shows the structure of a cover member and a food tray. It is a perspective view which shows the structure of a pinion gear. It is the DD sectional view taken on the line of FIG. It is the DD sectional view taken on the line of FIG. 10, Comprising: It is a figure which shows the fully open state of the cover member of a decompression chamber. It is the perspective view which looked at the structure of the decompression chamber from diagonally front upper, and is a figure which shows the fully open state of a cover member. It is the GG sectional view taken on the line of FIG. It is a fragmentary sectional view which shows an example of the junction part of the outline member divided | segmented up and down which comprises the decompression chamber by this invention. It is a fragmentary sectional view which shows the other Example of the junction part of the outer shell member divided | segmented up and down which comprises the decompression chamber by this invention. It is a fragmentary sectional view which shows the further another Example of the junction part of the outline member divided | segmented up and down which comprises the decompression chamber by this invention. It is the figure which showed the lock release state of the lid member by the lid member of the decompression chamber shown in FIG. 17, the support part of the opening / closing handle, and the opening / closing handle around the lid lock guide groove member. It is the figure which showed the state before the lock | rock around the cover member of a decompression chamber shown in FIG. 17, the support part of an opening-and-closing handle, and a cover lock guide groove member. It is the figure which showed the cover member locked state by the cover member of the decompression chamber shown in FIG. 17, the support part of an opening / closing handle, and the opening / closing handle around a cover lock guide groove member. It is a figure which shows the state which takes out a cover member and a food tray from a decompression chamber. It is a schematic plan view explaining the meshing of the rack and pinion gear and the positional relationship between the outer shell member and the food tray. It is DD sectional drawing of FIG. 10 which shows the state in the middle of opening and closing of a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of removal of a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of removal of a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of removal of a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of removal of a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a fragmentary sectional view explaining the procedure of attachment with a cover member and a food tray. It is a perspective view which shows an example of a structure of a cover member. It is a figure which shows the example of installation of a decompression chamber. It is a figure which shows the example of installation of a decompression chamber. It is a figure which shows the example of installation of a decompression chamber. It is a sectional side view of the decompression chamber which concerns on the other Example of this invention. It is a perspective view of the outline member of FIG.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a front view of a refrigerator main body 1 according to an embodiment to which the present invention is applied. FIG. 2 is a cross-sectional conceptual diagram taken along line AA in FIG.

<Overall configuration of refrigerator body 1>
As shown in FIG. 1, the refrigerator main body 1 of the present embodiment is a refrigerating room 2 that is a refrigerating temperature zone storage room at around 6 ° C. at the top and a refrigerating temperature room storage room at around 6 ° C. at the bottom. Vegetable rooms 6 are arranged respectively. Between the refrigerator compartment 2 and the vegetable compartment 6, a freezing compartment having a freezing temperature zone of 0 ° C. or lower (for example, a temperature zone of about −20 ° C. to −18 ° C.) that is adiabatically separated from both the compartments. An ice making room 3, a quick freezing room 4 and a freezing room 5 are arranged. As shown in FIG. 2, each storage chamber is partitioned and arranged by an upper heat insulating partition wall 31a and a lower heat insulating partition wall 31b.

  Further, a decompression chamber 13 is provided in the refrigerator compartment 2. In this embodiment, the decompression chamber 13 is a chilled temperature zone and is a storage chamber in a temperature zone of about 1 ° C.

  The refrigerating room 2 includes, on the front side, refrigerating room doors 2a and 2b with double doors (so-called French type) divided into left and right. The ice making room 3, the quick freezing room 4, the freezing room 5, and the vegetable room 6 are provided with a drawer type ice making room door 3a, a quick freezing room door 4a, a freezing room door 5a, and a vegetable room door 6a, respectively.

  As shown in FIG. 2, the outside of the refrigerator body 1 and the inside of the refrigerator are separated by a heat insulating box 10 filled with a foam heat insulating material (foamed polyurethane) between the inner box 10a and the outer box 10b.

  The inside of the refrigerator is separated from the refrigerator compartment 2, the quick freezing compartment 4 and the ice making room 3 (see FIG. 1, the ice making room 3 is not shown in FIG. 2) by the upper heat insulating partition wall 31a. The freezer compartment 5 and the vegetable compartment 6 are separated by 31b.

  A plurality of door pockets 32 are provided inside the refrigerator compartment doors 2a and 2b (see FIGS. 1 and 2). The refrigerator compartment 2 is provided with a plurality of shelves 37. The refrigerator compartment 2 is partitioned into a plurality of storage spaces in the vertical direction by the shelves 37, and the decompression chamber 13 is provided in the lowermost storage space.

As shown in FIG. 2, the quick-freezing chamber 4, the freezing chamber 5 and the vegetable chamber 6 are provided with storage containers 3b, 4b, 5b and 6b integrally with a door provided in front of each storage chamber. Yes.
The ice making room door 3a, the quick freezing room door 4a, the freezing room door 5a and the vegetable room door 6a are each put on a handle portion (not shown) and pulled out to the front side, thereby storing containers 3b, 4b, 5b, 6b. Can be pulled out.

  The decompression chamber 13 is provided with a decompression chamber lid 16 that opens and closes the front opening. When the refrigerator compartment doors 2a, 2b are opened, the drawer container of the decompression chamber 13 can be pulled out by placing the hand on the handle portion 27 of the decompression chamber lid 16 and pulling the lid member 16 forward. Yes. Details thereof will be described later.

  In the refrigerator body 1, a refrigeration cycle for performing refrigeration and refrigeration is configured by connecting a compressor, a condenser, a capillary tube, an evaporator serving as a cooling source that takes away the heat of vaporization of the refrigerant, and a compressor again in this order. (Not shown). The evaporator serving as a cooling source is installed behind the ice making chamber 3, the quick freezing chamber 4 and the freezing chamber 5, and the cooler of the evaporator is sent to the ice making chamber 3, the quick freezing chamber 4 and the freezing chamber 5 by the blower fan. Sent. Moreover, it sends to each storage room of the refrigerator compartment 2 and the vegetable compartment 6 through the damper apparatus which can be opened and closed when it becomes below predetermined refrigeration temperature. In addition, after the cool air is blown into each storage chamber, it has a circulation structure in which it is cooled again by the evaporator and blown. Each storage chamber is maintained at a predetermined temperature by temperature control by a control device using a temperature sensor.

  Next, FIG. 3 shows a sectional view taken along line BB in FIG. The refrigerator compartment door 2a is supported so as to be rotatable about the support shaft S1. The refrigerator compartment door 2a is provided with a translucent resin-molded door pocket 32 for storing drinks or the like on the inner side. On the back surface of the refrigerator door 2a, there is provided a rotary partition 2a2 configured to be swingable by a biasing force of a torsion coil spring and a guide.

  The rotating partition 2a2 prevents cold air from leaking between the refrigerator compartment doors 2a and 2b at the position along the left refrigerator compartment door 2a when the refrigerator compartment doors 2a and 2b are closed (see FIG. 1). On the other hand, when the refrigerator door 2a is opened, the refrigerator door 2a is configured to swing in the thickness direction (indicated by a two-dot chain line) so as not to disturb the user.

  Further, the right refrigerator compartment door 2b is supported so as to be swingable about the support shaft S2, and a translucent resin-molded door pocket 32 into which a drink or the like is placed protrudes on the inner side.

<Configuration of decompression chamber 13 which is a gas control chamber>
The decompression chamber 13 shown in FIG. 3 is a gas regulation chamber in which the internal air is sucked by the vacuum pump 12 and decompressed to an atmospheric pressure lower than the atmospheric pressure, for example, 0.8 atmospheric pressure (80 kPa). That is, the decompression chamber 13 creates a special air atmosphere for preventing oxidation of food, maintaining the freshness of vegetables, and the like.

  As shown in FIG. 2, a cold air inlet 19 of the refrigerator compartment 2 is provided at the rear of the decompression chamber 13, and the decompression chamber 13 is opened by sucking air around the decompression chamber 13 and flowing the cool air as shown by an arrow. Cool indirectly.

  As shown in FIG. 3, when the refrigerator compartment door 2b is closed, a predetermined space is formed between the door pocket 32 of the refrigerator compartment door 2b and the lid member 16 of the decompression chamber 13 so as not to contact each other. ing.

  FIG. 4 shows a door pocket 32 provided in the left refrigerator compartment door 2a with the left refrigerator compartment door 2a closed by opening the refrigerator compartment doors 2a and 2b and then opening the lid member 16 of the decompression chamber 13. Indicates the left end of the lid member 16 and the lid member 16 is inclined. In such a state, the lid member 16 does not move smoothly in the back surface direction, so the refrigerator compartment door 2a is not closed. Therefore, even when a force is applied only to the end portion of the lid member 16, it is desirable to move while keeping parallel without being inclined.

  Next, FIG. 5 is a perspective view of the configuration of the decompression chamber 13 as viewed obliquely from above and front. The decompression chamber 13 has an opening 14r on the front surface (see FIG. 6), and is moved to the front and rear by an outer shell member 14 (storage container) that is divided into two vertically divided in a substantially rectangular parallelepiped shape that is long in the back. An outer peripheral wall is formed by the lid member 16 that opens and closes the opening 14r.

  That is, a lid member 16 that opens and closes is provided in order to put a stored product into and out of the decompression chamber 13. Furthermore, on the outer surface of the outer member 14, reinforcing ribs that increase the section modulus and improve the strength are erected in a straight line shape or a lattice shape. The shape of the reinforcing rib is not limited thereto, and any shape may be used as long as the section modulus of the outer member 14 is increased to improve the strength.

  The decompression chamber 13 is placed on the upper heat insulating partition wall 31a as in the present embodiment, placed on one of the shelves 37, or the upper wall portion (the heat insulating box body of the shelf 37 or the storage chamber). 10 may be hung by the hanging means 100 (see FIGS. 42 to 44). That is, the container of the decompression chamber 13 can be appropriately employed as long as it is a known installation method.

<Schematic shape of outer member 14>
Next, the configuration of the outer member 14 will be described with reference to FIGS. FIG. 6 is a simplified perspective view of the outer member 14 as viewed from the front upper side. The outer member 14 has a configuration in which the lower case 140 (first outer member) and the upper case 141 (second outer member) are joined to each other at the joint 142 while maintaining airtightness, and are separated vertically for convenience of explanation. It is shown as an exploded view. FIG. 7 is a view in the direction of arrow C in FIG. 8 is a cross-sectional view taken along the line KK of FIG. 6 to 7 are schematic views of only the virtual outer member 14 from which the reinforcing rib is removed in order to make it easier to grasp the shape of the outer member 14.

  The lower case 140 of the outer member 14 is resin-molded using ABS (resin containing acrylonitrile, butadiene, styrene), AS (resin containing acrylonitrile, styrene) or the like. Both side walls 140a and 140b, a bottom wall 14c, and a rear wall 140d are integrally formed. Further, the lower case 140 forms a front opening 14r and an upper opening 140e. That is, it has a shape in which two surfaces are opened. The connecting portion 140f constituting the upper side of the front opening 14r and the front side of the upper surface opening 140e is connected to the left and right side walls 140a and 140b, respectively. Furthermore, it has the junction part 142 provided seamlessly over the perimeter of the upper surface opening 140e.

  The upper case 141 of the outer member 14 is resin-molded using ABS (resin containing acrylonitrile, butadiene, styrene), AS (resin containing acrylonitrile, styrene), or the like. The upper case 141 is integrally formed in a shape having an upper surface wall 141e, both side surface walls 141a and 141b, a rear surface wall 141d, and a joint 142 on the entire periphery. The upper case 141 is formed so as to cover the upper surface opening 140e of the lower case 140 over the entire surface without any gap.

  That is, the side wall 14 a of the decompression chamber 13 is divided into a side wall 140 a of the lower case 140 and a side wall 141 a of the upper case 141. Similarly, the side wall 14b is divided into a side wall 140b of the lower case 140 and a side wall 141b of the upper case 141. Further, the rear wall 14d is divided into a rear wall 140d of the lower case 140 and a rear wall 141d of the upper case 141, respectively.

  As shown in FIGS. 3 and 4, a pump connection portion 14 i of an insertion hole, which is a connection portion with the vacuum pump 12, is provided behind the outer surface of the left side wall 14 a of the outer member 14.

  When the inside of the decompression chamber 13 is decompressed by the vacuum pump 12, a load from the atmosphere is uniformly applied to the entire surface of the outer member 14 due to the differential pressure between the external atmospheric pressure and the internal low pressure. Since the inside of the decompression chamber 13 is at a low pressure, this load is applied in such a direction that the entire outer member 14 is crushed from the outside to the inside. For example, if the planar dimension of the outer member 14 is 450 mm in width and 300 mm in depth, and the differential pressure is 0.2 atm, the load is about 270 kgf (about 2700 N).

  For this reason, it is necessary to increase the sectional modulus of each outer surface of the side wall 14a, 14b, the bottom wall 14c, the rear wall 14d, and the top wall 14e of the outer member 14 to improve the strength. Therefore, each surface of the outer member 14 is not a flat surface but has a substantially dome-shaped curved surface that is curved so as to protrude outward. Furthermore, as conceptually shown by a broken line in FIG. 6, it is preferable that the outer surface wall of the outer member 14 has a shape curved outward in both the depth direction and the left-right direction.

  Furthermore, a first recess 14z is provided from the center of the bottom wall 14c of the lower case 140. The bottom wall 14c has a curved shape that is curved so as to protrude from the inner surface to the outer surface, the center portion is formed at the lowest, and the first recess 14z is provided at the lowest position.

  An opening protrusion 14h extending from the vicinity of the opening 14r of the lower case 140 toward the rear wall 140d is provided in the vicinity of the side walls 14a and 14b of the bottom wall 14c, and when the food tray 17 is opened as described later. The food tray 17 is supported.

  The outer member 14 has a shape in which the opening 14r is longer in the width direction than in the height direction. Moreover, it is substantially circular arc shape which has height toward both sides from a center part. That is, the outer member 14 has a substantially rectangular parallelepiped shape having a flat horizontally long opening 14r. Thereby, the bottom wall 14c and the top wall 14e have a larger area than the other side walls 14a, 14b and the rear wall 14d. Since the load generated by the pressure difference from the atmospheric pressure when the inside is depressurized is proportional to the area, it is particularly necessary to ensure the strength of the bottom wall 14c and the top wall 14e. Since the load at this time is a load in a direction in which the outer member 14 is compressed and crushed from the outside, the strength is increased as a dome-shaped spherical shell that forms a part of a sphere, for example, a surface that receives the load. It is increasing.

  7 is a view in the direction of the arrow C in FIG. As shown in FIG. 7, the opening 14r has an outer edge shape around the side walls 14a and 14b, the bottom wall 14c, and the connecting portion 140f. Each wall surface of the outer member 14 has an arc shape that protrudes outward, and has a shape in which corners of the walls are connected by a smooth arc.

  In addition, the upper and lower sides of the opening 14r near the center are an upper surface opening support portion 14f and a lower surface opening support portion 14g that protrude toward the inside of the opening 14r.

  When a lid member 16, which will be described later, is closed, the packing 16p provided on the lid member 16 comes into pressure contact with the packing contact surface 14k, which is a convex portion provided along the edge of the opening 14r, and performs a hermetic seal. That is, the packing 16p is provided as a seal member that suppresses the movement of gas between the lid member 16 and the opening 14r of the outer member 14.

  8 is a cross-sectional view taken along the line KK of FIG. That is, a cross section in the longitudinal direction of the outer member 14 is shown, and the height dimension of the inner surface is described. The lower case 140 and the upper case 141 of the outer member 14 are integral parts that are molded with resin using ABS, AS, or the like. Molds for molding are roughly classified into an outer mold that forms the outer shape of each of the lower case 140 and the upper case 141 and an inner mold that forms the inner surface, and resin is injected into the mold and cooled. After that, the inner mold is pulled out to take out the lower case 140 and the upper case 141 from the mold.

<Die removal direction and shape>
In the present embodiment, as shown in FIG. 8, if the outer mold of the upper case 141 is pulled out in the direction of arrow AA, and the inner mold is pulled out in the direction of arrow AB, the upper surface wall 141e further extends from the upper end of the opening 14r. A shape that protrudes upward, for example, a dome shape can be used.

  On the other hand, the outer mold of the lower case 140 is provided with a side mold that is pulled out in the direction of the arrow BB, the inner mold is pulled out in the direction of the arrow BC, and further, the inside of the opening 14r is pulled out toward the opening 14r (arrow BD direction). In the range of M molded by the inner mold instead of the side mold, the bottom wall 14c can have a shape that protrudes further below the lower end of the opening 14r, for example, a dome shape. Furthermore, a projection such as a partial second recess 14w, a first recess 14z, or a lower guide rail 14y may be provided. Here, the 2nd recessed part 14w and the 1st recessed part 14z are provided in the range which does not protrude below the lower end surface 14q which is the lowest part of the lower case 140. As shown in FIG.

  The inner mold of the lower case 140 further includes a slide mold (not shown) because an upper guide rail 14s that supports a drawer container 17 to be described later protrudes inward.

  As described above, the top wall 141e and the bottom wall 14c are formed in a dome shape that protrudes outward, and the inner surface height ra of the outer member 14 can be made larger than the dimension rh of the opening 14r. It is not necessary to have a tapered shape. Therefore, it is suitable for enlarging the internal volume of the outer shell member 14 and increasing the rigidity.

  Between the opening 14r and the upper surface opening 140e, as shown in FIG. 6, a connecting portion 140f integrated with the lower case 140 is provided to seamlessly configure the periphery of the opening 14r and the upper surface opening 140e. The opening can be closed by the lid member 16 or the upper case 141 to maintain airtightness.

<Partition surface shape>
Next, the shape of the joint 142 between the upper case 141 and the lower case 140 will be described. As shown in FIG. 8, the upper case 141 and the lower case 140 are flat surfaces inclined rearwardly downward from the connecting portion 140f near the upper end of the opening 14r toward the center in the height direction of the rear wall 14d. A joint 142 is provided along the line. The upper case 141 constitutes a part of the outer member 14 composed of a dome-shaped upper surface 141e, side surfaces 141a and 141b, and a rear surface 141d, and the portion is convex from the joint 142 by a height 141t. In addition, the strength to support the load at the time of decompression is obtained in cooperation with the ribs disposed around the periphery.

  Here, if the dividing surface is a surface that has less inclination and is almost horizontal as indicated by a one-dot chain line 142b in FIG. 8, the convex amount from the joint 142b is reduced, and the shape of the upper case 141 is flat. Get closer. Therefore, the rigidity is reduced and the deformation during decompression is increased.

  In addition, as shown by a two-dot chain line 142c in FIG. 8, when the shape is a combination of a straight line and an arc, the convex amount of the upper case 141 is large and the rigidity is easily obtained. If there is a dimensional error in the radius R of the arc forming the joint portion of the case 140, the arcs do not completely coincide and a gap is likely to occur. Further, if the position of the upper case 141 is shifted in the right direction in FIG. 8, a gap is formed in the inclined parting surface 142 d, so that the upper case 141 and the lower case 140 are difficult to adhere to each other. That is, in order to keep the joint 142 in close contact with each other, high accuracy is required for the shape and dimensions of the surface of the joint and the positional relationship between the upper case 141 and the lower case 140, and it is difficult to keep the airtightness. It is.

  In this embodiment, as shown by a dividing surface 142a in FIG. 8, the dividing surface is gradually moved from the vicinity of the rear of the upper surface of the opening 14r toward the rear so as to become a plane connecting the substantially central portion of the rear wall 140d of the outer member 14. Tilt to descend. In this configuration, the upper case 141 does not have a thin plate shape, and the thickness 141t can be appropriately secured. Since the dividing surface 142a is an inclined plane, even if a positional deviation occurs between the upper case 141 and the lower case 140, there is no change in the close contact state. That is, since the surfaces of the joint portion 142 are flat with each other, the accuracy is easily obtained, and the airtightness is easily maintained even when the positional relationship between the upper case 141 and the lower case 140 is low.

  If it is set as said structure, since both the upper case 141 and the lower case 140 can be shape | molded with resin, there exists an effect that the outer shell member 14 can be comprised cheaply.

  The outer member 14 may have an inclined surface shape in which the relationship between the lower case 140 and the upper case 141 is reversed so that the dividing surface 142a gradually increases from the opening 14r toward the back (see FIGS. 45 and 46).

<Seal configuration>
Next, a configuration in which the upper case 141 and the lower case 140 are joined in an airtight manner at the joining portion 142 will be described with reference to FIGS. 21 to 23 which are enlarged views of a Q portion in FIG.

  FIG. 21 shows a first embodiment, FIG. 21 (a) shows a state in which the inside of the decompression chamber 13, that is, the inside of the outer member 14, is atmospheric pressure, and FIG. 21 (b) shows a state in which the pressure is reduced.

  The joint 142 between the upper case 141 and the lower case 140 sandwiches a round packing 146 formed of a flexible member such as silicon rubber formed in a circular shape with a circular cross section, and a screw boss provided on the lower case 140 In this configuration, 140 g and a screw boss 141 g provided on the upper case 141 are fastened by a screw 143. The screw boss 141g of the upper case 141 and the screw boss 140g of the lower case 140 are loosely fitted with a gap 144a, and are supported so as to be movable in the axial direction of the screw 143, that is, in the vertical direction in the figure. The screw bosses 140g and 141g are provided at approximately equal intervals along the dividing surface 142a, for example, about 10 to 15 places on the entire circumference.

  In the state of atmospheric pressure shown in FIG. 21A, the round packing 146 is sandwiched between the lower case 140 and the upper case 141 and, for example, about 5% of the diameter is crushed by the fastening force of the screws 143. Yes, and tightly adhere to the entire circumference of the joint 142 to keep airtight.

  When the vacuum pump 12 is driven and the inside of the outer member 14 is depressurized, if the internal and external differential pressure is 0.2 atm in the lower case 140 and the upper case 141, as described above, it is as large as about 270 kgf (about 2700 N). A pressure is applied under load. This load is applied to the round packing 146 sandwiched between the lower case 140 and the upper case 141 to crush, for example, about 15% of the diameter and maintain high airtightness that can maintain the pressure difference inside and outside. As the round packing 146 is crushed and deformed, the upper case 141 is close to the lower case 140 and the gap 144a is reduced to 144a '. Occurs.

  22A and 22B show a second embodiment. FIG. 22A shows a state in which the inside of the decompression chamber 13, that is, the inside of the outer member 14, is atmospheric pressure, and FIG. 22B shows a state in which the pressure is reduced.

  The difference from the first embodiment is that, instead of the round packing 146, a packing 147 formed in an annular shape with a substantially square cross-sectional shape having a recess 147a in which the center of the outer periphery of the cross section is recessed on the inner side is provided in the lower case 140. To the convex packing contact portion 140h. Even when the lower case 140 and the upper case 141 are slightly tilted or when the accuracy of the abutting surface is low, the packing 147 is elastically deformed flexibly into the recess 147a, and the deviation is absorbed and the lower case 140 and the upper case 141 are absorbed. The gap can be reliably sealed.

  When the vacuum pump 12 is driven and the inside of the outer member 14 is depressurized, the concave portion 147a of the packing 147 is crushed, and like the round packing 146, for example, about 15% of the thickness can be crushed to maintain the internal and external differential pressure. Keep the airtight.

  FIG. 23 shows a third embodiment in which an airtight member such as packing is not used. A welded portion 148 that is a rib provided on the entire circumference along the joint 142 is provided around the upper case 141. The lower case 140 and the upper case 141 are pressed against each other in the direction of the arrow, and vibration is applied. Part 148 is dissolved. And it is the structure which welds the lower case 140 and the upper case 141 integrally, and obtains airtightness. With such a configuration, packing and screws as in the first and second embodiments are unnecessary, and the outer member 14 can be realized with a simple configuration at low cost.

  In the present embodiment, since the joining portion 142 has an inclined planar shape, the distribution of the pressure contact force when the lower case 140 and the upper case 141 are pressed against each other is uniform, and the frictional heat generated when vibration is further applied. Since the generation is uniform, it can be reliably welded and sealed. In addition, the structure provided in the lower case 140 instead of the upper case 141 may be sufficient as the welding part 148. FIG. In addition to the above vibration welding, means such as hot plate welding (contact or non-contact) and ultrasonic vibration may be used.

  As shown in FIG. 6, the connecting portion 140f of the lower case 140 has a low strength because it is a thin region sandwiched between the opening 14r and the upper surface opening 140e. According to the third embodiment, the connecting portion 140f is welded to and integrated with the upper case 141 via the welded portion 148. Therefore, the strength is higher than that of the connecting portion 140f alone, and deformation at the time of decompression can be prevented, which is further preferable. Further, the outer member 14 may be configured by bonding the upper case 141 and the lower case 140 with an adhesive, for example, a silicon rubber-based adhesive.

  Here, when the inside of the decompression chamber 13 is depressurized, all the surfaces of the outer shell member 14 are subjected to a load due to atmospheric pressure, and are deformed in the direction of being crushed inward. large. When the joining part 142 is mutually fixed by the welding part, the joint part 142 does not produce the rotation bending to the direction pulled in. Therefore, the amount of deflection at the time of decompression can be reduced.

<Material>
The material of the outer member 14 is preferably a material that can withstand the load caused by the differential pressure when the inside is decompressed. In addition, a material having high rigidity is desirable in order to reduce the amount of deflection at the time of decompression and not to compress the food stored inside. As an example, as a fibrous reinforcing filler, an ABS material reinforced by mixing glass fibers or carbon fibers can be used. As a result, the bending strength is increased and the Young's modulus (elastic coefficient) is increased, so that the outer member 14 can be suitably used.

As shown in FIG. 8 (and FIG. 6, FIG. 7, FIG. 9, FIG. 11, etc.), inside the opening 14r of the outer member 14, an upper surface opening support portion 14f that protrudes inward from the upper surface wall 14e, a bottom wall A lower surface opening support portion 14g that protrudes inward from 14c is provided on the rear surface side of the front opening 14r.
At the edge of the opening 14r, there is a packing contact surface 14k, the upper surface opening support portion 14f is connected to the inclined surface 14m, and the lower surface opening support portion 14g is connected to the inclined surface 14n.

<Relationship between lid member 16 and opening 14r>
Next, the relationship between the lid member 16 and the opening 14r will be described. 9 and 11, the lid member 16 is closed, and reinforcing support portions H (shown by alternate long and short dash lines) provided on the lid member 16 are upper surface opening support portions 14 f and lower surface opening support portions 14 g of the outer member 14. The state inserted between is shown.
The distance between the upper surface opening support part 14f and the lower surface opening support part 14g, that is, the height dimension of the opening 14r is slightly larger than the height dimension of the reinforcing support part H. Thereby, the reinforcement support part H is inserted smoothly.

  Here, when the inside of the decompression chamber 13 is decompressed and a load due to the differential pressure of the atmospheric pressure is applied to the outer surface of the outer member 14, the outer member 14 is compressed and the gap is eliminated. Then, the upper surface opening support portion 14f and the lower surface opening support portion 14g are in contact with the upper and lower sides of the reinforcement support portion H, respectively. Thereby, since it is not compressed any more, the deformation of the opening 14r can be prevented.

  On the other hand, in the contact portion, the outer member 14 is compressed by the atmospheric pressure from the outside and is in contact with the reinforcing support portion H while being bent inward. That is, it does not contact uniformly, but comes into contact with the outer member 14 at the left and right ends of the reinforcing support H, and a reaction force F1 is generated between the outer member 14 and the outer member 14. Here, as shown in FIG. 9, the width of the upper surface opening support portion 14f is approximately L2, and the width of the opening 14r outside the opening support portion is approximately L1. Then, it is desirable that L1 and L2 are configured to be substantially equal. By doing in this way, the load by the differential pressure added to the range of the upper surface reinforcement part 14f and the range of the upper surface wall 14e becomes respectively substantially equal and equal. Therefore, a load is not intensively applied to a specific portion, and the stress generated in the upper surface opening support portion 14f and the range of the opening outside thereof is almost equal to prevent damage due to repeated loads and increase the life. High reliability can be achieved.

  The widths of the bottom wall 14c and the lower surface opening support portion 14g are preferably similar in size and shape.

  As described above, in addition to the shape of the outer member 14, each of the side walls 14a and 14b, the bottom wall 14c, the rear wall 14d, the top wall 141e, the top opening support 14f, and the bottom opening support 14g, respectively. On the outer surface, reinforcing ribs that increase the section modulus and improve the strength are erected in a straight line shape, a lattice shape, etc., and further strength against deformation due to differential pressure is secured.

  Guide rails 14s and 14s, which are protrusions along the depth direction, are provided on the inner surfaces of the side walls 140a and 140b of the lower case 140, and a pair of protrusions 17g and 17g provided on the food tray 17 to be described later are provided. The rear end side of the food tray 17 is supported.

  The outer member 14 is shaped as described above, and the upper case 141 and the lower case 140 molded from resin are joined at the joining portion 142. As a result, the outer member 14 can be simplified and reduced in weight, and can be configured at low cost, and both expansion of the internal volume and increase in rigidity can be achieved.

<Overall configuration of decompression chamber 13>
Hereinafter, the configuration and operation of the decompression chamber 13 including the outer member 14 will be described in detail. FIG. 10 is a conceptual diagram of the decompression chamber 13 shown in FIG. 11 is a cross-sectional view taken along the line DD of FIG. 12 is a cross-sectional view taken along line FF in FIG. 13 is a cross-sectional view taken along line EE in FIG. 14 is a perspective view of the food tray 17 and the lid member 16 removed from the outer member 14 and viewed from the direction A in FIG. FIG. 15 is a perspective view as seen from the direction B of FIG. FIG. 16 is a perspective view showing the configuration of the pinion gear 15 provided in the outer member 14.

<Food tray (drawer container)>
The food tray 17 (drawer container) disposed in the outer member 14 is a transparent resin molded product such as AS. As shown in FIGS. 11 to 15, both side walls 17a and 17b, a bottom wall 17c, a rear wall 17d, and a front wall 17e are provided.

  The front wall 17e of the food tray 17 is formed with a concave portion 17f for arranging a reinforcing support portion H described later, and a central side wall portion 17h connecting the front wall 17e and the concave portion 17f along the reinforcing support portion H. Yes. 12, 14, and 15, the food tray 17 is attached to the lid member 16 on the central side wall portion 17 h and the side walls 17 a and 17 b, and 2 for interlocking with the opening / closing operation of the lid member 16. A pair of mounting claws 17t1 and 17t2 are formed. A pair of left and right projections 17g and 17g are formed in the vicinity of the rear wall 17d of the side walls 17a and 17b. A stopper 17n that is a convex portion is formed on the lid member 16 side of the concave portion 17f.

  The two pairs of mounting claws 17t1 and 17t2 are formed in a semi-cylindrical shape with the lower part opened and one side extended downward, and engage with columnar protrusions 16g1 and 16g2 provided on the lid member 16. . Thus, the food tray 17 is fixed to the lid member 16 and interlocked with the opening / closing operation of the lid member 16.

  Therefore, the user can easily take out the food in the food tray 17 by visually recognizing the inside of the food tray 17 that is pulled out as the lid member 16 opens and closes.

<Guide rail>
As shown in FIGS. 14 and 15, the food tray 17 and the lid member 16 are configured to open and close in conjunction with each other. The bottom wall 17c of the food tray 17 is provided with guide ribs 17j, 17j that are elongated in the opening and closing direction. Guide protrusions 14t and 14t for mounting guide ribs 17j and 17j are provided in the vicinity of the opening 14r of the bottom wall 14c of the outer member 14. On the rear side of the bottom surface of the food tray 17, a stopper 17m that is a step is provided. The stopper 17m is slidably mounted on the lower guide rail 14y provided on the bottom surface of the outer member 14.

  On the side close to the opening 14r of the food tray 17, that is, the lid member 16 side, the guide rib 17j is placed on the guide protrusion 14t, and the upper surfaces of the protrusions 17g and 17g provided near the rear surface of the food tray 17 are the guide rails 14s, Supported by the lower side of 14s. The lower guide rail 14y is provided with a stopper 14v that is a step. When the lid member 16 and the food tray 17 are opened in conjunction with each other, the stopper 17m hits the stopper 14v at the fully opened position, and is restricted from opening further.

  With the above configuration, the food tray 17 is guided in the front-rear direction (the left-right direction of the paper surface of FIG. 11 and the vertical direction of the paper surface of FIG. 13) in conjunction with the lid member 16.

<Bottom rack and pinion>
Next, FIG. 17 is a cross-sectional view of the decompression chamber 13 showing a process in which the lid member 16 is fully opened.
FIG. 18 is a cross-sectional view of the decompression chamber 13 showing the fully opened state of the lid member 16, and further shows a state where condensation has occurred inside the outer member 14. FIG. 19 is a perspective view showing the fully opened state of the lid member 16 as in FIG.

  On the lower surface of the bottom wall 17c of the food tray 17, that is, the side facing the bottom wall 14c of the outer shell member 14, two rows of racks 17k, which are linear gears in the front-rear direction, are provided symmetrically at a distance from each other. .

  A pinion gear 15 shown in FIG. 16 is rotatably supported in a second recess 14w provided in the bottom wall 14c of the outer member 14 in parallel with the opening 14r. The pinion gear 15 includes a pair of left and right pinion gears 15a that are coupled to each other by a connecting shaft 15b and rotate synchronously as a unit, and a support shaft 15c that further protrudes outside the pinion gear 15a.

  The second recess 14w of the outer member 14 has a substantially semi-cylindrical shape larger than the diameter of the pinion gear 15a, and the support shaft 15c of the pinion gear 15 is rotatably fitted to the left and right ends of the second recess 14w. This is a support recess 14x. Since the pinion gear 15 is simply dropped into the second recess 14w from above, the pinion gear 15 can be removed simply by removing the food tray 17 and picking it up with a finger and lifting it upward. For example, even when the second recess 14w and the pinion gear 15 are dirty, they can be easily removed and cleaned or washed.

  When the food tray 17 is arranged in the outer member 14, the rack 17k provided in the food tray 17 and the pinion gear 15a provided in the second recess 14w of the outer member 14 are arranged in meshing positions. Yes. However, the rack 17k does not mesh with the pinion gear 15a over the entire range in which the lid member 16 and the food tray 17 are opened and closed, but the rack 17k is within the range of the distance L1 from the fully closed position of the lid member 16 and the food tray 17. Is not provided. This operation and effect will be described later.

  The pair of racks 17k are formed integrally with the food tray 17, and the pair of pinion gears 15a rotate integrally. Since such a synchronizing means is provided, when the food tray 17 moves in the front-rear direction, the rack and the pinion continue to engage with each other, and the lid member 16 is always kept parallel to the opening 14r. It is a configuration that moves. That is, even if a force is applied to the end portion of the lid member 16 instead of the center portion, the lid member 16 or the food tray 17 does not tilt left and right, and can move stably while maintaining parallelism.

  According to the above configuration, it is not necessary to provide a rail member or the like in order to open and close the lid member 16 and the food tray 17 back and forth, and it is also necessary to provide a component such as a support shaft for supporting the pinion gear. The lid member 16 and the food tray 17 can be opened and closed stably with a simple configuration.

<Configuration of lid member 16>
As shown in FIG. 5, the lid member 16 has an opening / closing handle 26 rotatably supported around a support shaft 16s provided on both sides thereof. Further, the lid member 16 includes a differential pressure relief valve V shown in FIG.

  The user holds the opening / closing handle 26, and the lid member 16 is opened / closed and locked when the lid member 16 is closed, and the differential pressure relief valve V is opened / closed.

  When the decompression chamber 13 is decompressed by the vacuum pump 12, the load applied to the lid member 16 increases due to the differential pressure between the atmospheric pressure outside the decompression chamber 13 and the decompressed pressure inside the decompression chamber 13. . Thereby, in order to open the cover member 16 directly, a user requires considerable force.

  Therefore, by opening the differential pressure relief valve V, the inner and outer spaces of the lid member 16 are inserted, the pressure difference between the inside and the outside is eliminated, the load due to the differential pressure is eliminated, and the lid member 16 can be easily opened. Yes.

  As shown in FIG. 11, the lid member 16 is provided with an elastic packing 16p on the inner peripheral edge thereof that comes into contact with the outer member 14 when closed. The packing 16p provides a seal between the outer member 14 and the lid member 16.

As shown in FIG. 17, the packing 16 p is formed in an annular shape having a recess 16 p 1 in which the center of the outer periphery of the cross section is recessed on the inner side. Even when the cover member 16 is closed with a slight inclination with respect to the outer shell member 14, the packing 16 p is elastically deformed in the recess 16 p 1 to absorb the deviation, and the gap between the outer member 14 and the outer cover member 16. Can be reliably sealed.
The packing 16p can be provided on the outer member 14 side without being provided on the lid member 16.

  As shown in FIG. 5, the lid member 16 is formed of a resin such as ABS whose left and right end portions 16 h are opaque, and a transparent portion such as a transparent AS so that the central portion 16 c 2 can visually recognize food stored in the decompression chamber 13. Molded with resin.

  As shown in FIG. 5, the distance between the side portions 16c1 and 16c1 of the lid member 16 and the turning locus of the rod 27 of the opening / closing handle 26 is set to a predetermined value or less, for example, 7 mm or less. That is, the both side portions 16c1 and 16c1 of the lid member 16 are formed in a shape projecting outward substantially along an arcuate locus along which the rod body 27 of the opening / closing handle 26 moves.

  As shown in FIG. 11, the center portion 16c2 of the lid member 16 has a space in which the handle operating portion 36 of the opening / closing handle 26 is positioned so that the user's hand can enter from the outer surface side. It is formed in a concave shape.

  As shown in FIG. 11, a reinforcing support portion H that is a vertical support portion of a front opening having a shape protruding inward is formed on the inner side of the center portion 16 c 2 of the lid member 16.

  20 is a horizontal sectional view in the GG direction in FIG. The reinforcing support portion H of the lid member 16 is provided near the center of the back surface of the lid member 16 as shown in FIGS. The reinforcing support portion H is formed by continuously forming an outer peripheral upper wall surface H1, an outer peripheral lower wall surface H2, and both side wall surfaces H3 standing on the inner side, and a plurality of reinforcements are provided between the outer peripheral upper wall surface H1 and the outer peripheral lower wall surface H2. Ribs hr are formed extending in the vertical direction.

  In addition, columnar projections 16g1, 16g2, and 16g3 for fixing the lid member 16 and the food tray 17 are formed on the outer surfaces of both side wall surfaces H3 of the reinforcing support portion H of the lid member 16.

  A pair of mounting claws 17t1 and 17t2 (see FIGS. 14 and 15) of the food tray 17 are engaged with the protrusions 16g1 and 16g2, and the food tray 17 is linked to the opening / closing operation of the lid member 16 and pulled out to the outside. The user can easily see and take out the food in the food tray 17.

  As described above, when the outer shell member 14 is depressurized by the vacuum pump 12, a large load is applied due to a differential pressure between the external atmospheric pressure and the internal low pressure.

  As shown in FIG. 11, when the lid member 16 is closed, the reinforcing support portion H inside the lid member 16 contacts the upper surface opening support portion 14 f and the lower surface opening support portion 14 g of the outer member 14 in the decompression chamber 13. In contact therewith, due to the differential pressure between the atmospheric pressure outside the decompression chamber 13 and the low pressure inside the decompression chamber 13, the load applied from above to the upper surface wall 141e of the outer member 14 and the upper surface opening support portion 14f, and the bottom wall 14c of the outer member 14 And the load due to the differential pressure applied to the lower surface opening support 14g from below, and the deformation of the decompression chamber 13 is suppressed by these loads.

  Further, as shown in FIGS. 10 and 11, a differential pressure relief hole 16 a that is inserted into the decompression chamber 13 of the differential pressure relief valve V is provided in the central portion 16 c 2 of the lid member 16.

  As shown in FIG. 11, the lid member 16 has a valve opening / closing member 35 having a valve body 35t made of rubber having elastic properties and flexibility for opening / closing the differential pressure release valve V around the support shaft 35s. It is provided in a freely rotatable manner.

  Here, the support shaft 35s on which the valve opening / closing member 35 rotates and the support shaft 16s (see FIGS. 5 and 11) on which the opening / closing handle 26 rotates are configured concentrically. The valve opening / closing member 35 is linked to the opening / closing operation of the valve body 35t.

<Configuration of the opening / closing handle 26>
As shown in FIG. 5 (and FIG. 11, FIG. 17, FIG. 18, FIG. 20, etc.), the opening / closing handle 26 has a rod body 27 composed of an aluminum rod, and one end portion at the left and right ends of the rod body 27. There are provided metal support portions 28 and 29 that are respectively fixed, and a handle operation portion 36 that is used for a handle operation by inserting a rod 27 in the center portion.

  The left and right support portions 28 and 29 of the opening / closing handle 26 are supported at their center portions so as to be rotatable around the left and right support shafts 16s and 16s of the lid member 16, respectively. 29r is rotatably supported.

  As shown in FIG. 11, the opening / closing handle 26 is supported so as to be rotatable around support shafts 16 s, 16 s on the left and right side portions of the lid member 16. When the rod 27 is positioned at the lowermost part of the rotation trajectory around the left and right support shafts 16s, the lid member 16 is closed and locked by the opening / closing handle 26. On the other hand, as shown in FIG. 17, when the rod 27 is positioned above the rotation trajectory around the left and right support shafts 16 s, 16 s, the lid member 16 is unlocked by the opening / closing handle 26. Yes.

  The guide rollers 28r and 29r of the left and right support portions 28 and 29 of the opening / closing handle 26 are fitted into lid lock guide groove members 30 and 30 provided on the side walls 14a and 14b on both sides of the decompression chamber 13 so as to open and close. The lid member 16 is locked by the handle 26.

  24, 25, and 26 are enlarged views showing a process of locking the lid member 16 of the decompression chamber 13, the support portion 28 of the opening / closing handle 26, and the opening / closing handle 26 around the lid lock guide groove member 30 shown in FIG. is there.

  24 is a diagram showing the unlocked state of the lid member 16 by the opening / closing handle 26, FIG. 26 is a diagram showing the locked state of the lid member 16 by the opening / closing handle 26, and FIG. It is the figure which showed the state before the 26 lock.

  Since the left lid lock guide groove member 30 has the same configuration as the right lock guide groove member 30, the right lid lock guide groove member 30 will be described, and the left lid lock guide groove member 30 will be described. Is omitted.

  As shown in FIGS. 24 to 26, the lid lock guide groove member 30 is, for example, a resin-molded member, and guides the guide roller 28r in contact with the curved inner wall guide 30a in a side view. is there.

  The inner wall guide 30a of the lid lock guide groove member 30 is formed in the following shape in a side view.

  That is, as shown in FIG. 24, an intersection 30a1 is a point where a straight line connecting the support shaft 16s when the lid member 16 is unlocked by the opening / closing handle 26 and the axis of the guide roller 28r contacts the inner wall guide 30a. . Let c be the dimension between the intersection 30a1 and the support shaft 16s.

  As shown in FIG. 25, an intersection 30a2 is a point where a straight line connecting the support shaft 16s before the lid member 16 is locked by the opening / closing handle 26 and the axis of the guide roller 28r contacts the inner wall guide 30a. The dimension between the intersection 30a2 and the support shaft 16s is b.

  As shown in FIG. 26, an intersection 30a3 is defined as a point where a straight line connecting the support shaft 16s when the lid member 16 is locked by the opening / closing handle 26 and the axis of the guide roller 28r contacts the inner wall guide 30a. A dimension between the intersection 30a3 and the support shaft 16s is defined as a.

These a, b and c are
b (state before locking (FIG. 25))> a (locking state (FIG. 26))> c (lock releasing state (FIG. 24))
The shape of the inner wall guide 30a shown in FIGS. 24, 25, and 26 is formed in a side view.

  In the state before the lid member 16 is locked by the opening / closing handle 26 shown in FIG. 25, the dimension b between the intersection 30a2 and the support shaft 16s is the largest. As a result, as shown in FIG. 25, the guide roller 28 r of the support portion 28 abuts against the inner wall guide 30 a of the lid lock guide groove member 30, or twists. Therefore, the user who opens and closes the opening / closing handle 26 supported by the support portion 28 is given a feeling that the lid member 16 is locked. That is, the inner wall guide 30a is formed so as to lock after giving a click feeling.

When the user grasps the handle operating portion 36 of the opening / closing handle 26 and pushes the handle operating portion 36 of the opening / closing handle 26 downward from the state before the locking shown in FIG. 25 to reach the locked state shown in FIG.
b (state before locking (FIG. 25))> a (locking state (FIG. 26))
From this relationship, the degree to which the guide roller 28r of the support portion 28 in the neutral state squeezes the inner wall guide 30a of the lid lock guide groove member 30, that is, strongly contacts is eased. Thereby, in the transition operation of the user to the lock of the opening / closing handle 26, the opening / closing handle 26 is configured to give a feeling of being pulled from the state before the lock to the locked state.

  When opening the lid member 16, the user grasps the handle operating portion 36 of the opening / closing handle 26, and then goes through the state before the locking in FIG. 25 from the locking state in FIG. 26 to the opening / closing handle 26. The rod body 27 is lifted upward to reach the unlocked state shown in FIG. In this case, the dimension c between the intersection 30a1 and the support shaft 16s is the smallest compared to the state before the lock (see FIG. 25) and the locked state (see FIG. 26). Thus, although it passes once through the heavy touch portion before locking, the guide roller 28r of the support portion 28 guides the inner wall of the lid lock guide groove member 30 during the period from the state of FIG. 25 to the open state of FIG. An inner wall guide 30a is formed so that the opening / closing handle 26 can be operated with a gentle feel without touching 30a.

  The handle operating portion 36 (see FIGS. 11 and 17) of the opening / closing handle 26 has a function of a grip portion when the user operates the opening / closing handle 26 and a function of guiding opening / closing of the differential pressure relief valve V. ing. That is, the opening / closing operation by the rotation of the opening / closing handle 26 is linked to the opening / closing valve operation of the valve body 35t via the valve opening / closing member 35. As shown in FIG. 11, when the opening / closing handle 26 is closed, the valve body 35t is closed, and when the opening / closing handle 26 is turned upward and opened as shown in FIG. 17, the valve body 35t is opened.

  When the valve is opened, as shown by the arrows in FIG. 17, the difference between the pressure applied to the lid member 16 when the lid member 16 is opened as the outside air enters the decompression chamber 13 decompressed due to the pressure difference and the pressure difference is eliminated. The load due to pressure is eliminated, and the lid member 16 can be opened smoothly.

  After the lid member 16 is closed, for example, the user presses an operation switch (not shown) or the refrigerator doors 2a and 2b are closed and the door switch (not shown) is turned on. The air in the decompression chamber 13 is sucked and decompression is started.

  When the pressure reduction is started, the lid member 16 is pressed from the outside by the differential pressure between the atmospheric pressure and the internal low pressure, and the packing 16p is pressed against the outer member 14 by a pressure greater than the force locked by the handle. The recess 16p1 of the packing 16p is brought into close contact with the state shown in FIG. 11, and the packing 16p is crushed due to a large load due to the differential pressure between the atmospheric pressure and the internal low pressure, thereby generating a large surface pressure. Thus, the internal negative pressure can be maintained.

  With the above configuration, by driving the vacuum pump 12 to reduce the pressure, the inside of the decompression chamber 13 can be set to a negative pressure and the negative pressure can be maintained. Here, the outer member 14 of the decompression chamber 13 can be formed at low cost by being formed of a plastic material. Further, by adopting a vertically divided structure in which the outer member 14 is joined while keeping airtightness, the internal volume can be expanded and the strength can be ensured. Further, since the portions other than the front opening 14r are sealed, only the gap between the lid member 16 and the opening 14r is sealed with the packing 16p, so that the entire decompression chamber 13 can be kept hermetically sealed.

<Food tray support>
Next, a problem when the lid member 16 and the food tray 17 are set to the fully open position will be described with reference to FIG.

  As shown in FIG. 18, when the lid member 16 and the food tray 17 are in the fully opened position, the mass including the food stored in the food tray 17 is concentrated such that the center of gravity of the whole is added to the central portion of the food tray 17. It can be expressed as a load W. When fully opened, the load W is drawn further to the front side than the opening 14r, so that the lid member 16 and the food tray 17 are drooped by the load W as shown by 16 'and 17' shown by the one-dot chain line in FIG. The lid member 16 ′ contacts the upper heat insulating partition wall 28. Then, the opening / closing operation is hindered by the frictional resistance generated in the contact portion, which is not preferable. Therefore, an opening protrusion 14h extending from the vicinity of the opening 14r of the lower case 140 toward the rear wall 140d is provided in the vicinity of the side walls 14a and 14b of the bottom wall 14c, and the bottom surface of the food tray 17 is supported by the reaction force W ′. Thus, a configuration that prevents the lid member 16 and the food tray 17 from tipping down is desirable.

<Water measures>
Further, with reference to FIG. 13 (and FIGS. 18 and 22), a problem when water such as water droplets condensed on the inner side of the outer shell member 14 or water or liquid foreign matter is spilled on the outer side of the food tray 17 is described. These moisture 22 accumulates on the upper surface of the bottom surface of the outer member 14 and further flows into the second concave portion 14w, and freezes when the decompression chamber 13 is below the ice temperature. Since the pinion gear 15 is rotatably supported in the second recess 14w, if a part of the pinion gear 15 is submerged and frozen, the pinion gear 15 does not rotate, and as a result, the lid member 16 and the food tray 17 Open / close operation is hindered. Needless to say, in order to keep the decompression chamber 13 airtight, the outer member 14 cannot be provided with a drain outlet for draining the moisture 22 to the outside. Therefore, the moisture 22 that does not sublime or evaporate is accumulated in the outer member 14 as it is. Is done.

  A configuration in which a part of the pinion gear 15 is submerged by merely accumulating a small amount of moisture 22 inside the outer shell member 14 is not preferable because the opening and closing operations of the lid member 16 and the food tray 17 are frequently hindered by freezing. Therefore, it is desirable to increase the amount of moisture 22 that is accumulated before the rotation of the pinion gear 15 is affected, thereby reducing the frequency of the effects of freezing.

  As shown in FIG. 18, when the lid member 16 and the food tray 17 are opened and food is taken in and out, outside air having a high temperature and humidity flows into the inside and is condensed on the wall surface to form water droplets 22a. Descend and accumulate on the bottom. As described above, the bottom wall 14c has a curved shape that is curved so as to protrude downward, and the center portion where the first recess 14z is provided is lowest. Then, the water droplet 22a is generally collected in the first recess 14z. When the moisture 22 overflows, it flows into the second recess 14w. The same applies when water or liquid foreign matter is spilled outside the food tray 17. That is, by providing the first recess 14z in the center of the bottom surface of the outer member 14 that protrudes downward, the amount of moisture 22 until the rotation of the pinion gear 15 is affected can be increased.

  Moreover, as shown in FIG. 13, the water | moisture content 22 which flowed into the 2nd recessed part 14w is collected by the center part because the center part of the 2nd recessed part 14w is made into the shape of a hollow part lower than both ends. Thereby, the influence on the pinion gear 15 arrange | positioned at both ends can further be reduced.

With reference to FIG. 22, a configuration in which water droplets condensed on the inside of the outer member 14 are dropped will be described. In the dividing surface 142 between the upper case 141 and the lower case 140, the inner periphery of the upper case 141 is an extended portion 142 a that extends further downward than the V packing 147. That is, the inner peripheral lower end of the upper case 141 has a cross section extending downward from the outer peripheral upper end of the lower case 140. In this configuration, the condensed water droplets hang down along the inner wall, accumulate at the lower end of the extending portion 142a, and drop onto the inner wall of the lower case 140. Since the extending portion 142a extends downward from the V packing 147, water drops do not enter the V packing 147 side, and it is preferable that the water drops are reliably dropped from the inner side wall of the upper case 141 to the inner side wall of the lower case 140. is there.
Note that FIG. 23 has the same configuration and has the same effect.

<Removing the food tray>
Next, attachment and removal of the lid member 16 and the food tray 17 will be described with reference to FIGS. When the food tray 17 becomes dirty, the lid member 16 and the food tray 17 are removed and washed with water.

  FIG. 27 is a cross-sectional view when the food tray 17 and the lid member 16 are removed. FIG. 28 is a schematic plan view for explaining the meshing between the rack and the pinion gear and the positional relationship between the outer shell member and the food tray. FIG. 29 is a cross-sectional view showing an intermediate state of opening and closing.

  First, as shown in FIG. 18, the food tray 17 and the lid member 16 are set to the fully open position, and the front end of the lid member 16 is lifted and inclined as shown in FIG. At this time, the stopper 17m provided on the bottom surface of the food tray 17 is disengaged from the stopper 14v provided on the bottom surface of the outer member 14, so if it is moved obliquely forward (upper left in the figure in FIG. 27) The tray 17 and the lid member 16 can be pulled out integrally. If the reverse operation is performed, the food tray 17 and the lid member 16 can be attached. The rack 17k meshes with the pinion gear 15a and is closed by pushing the lid member 16 to the back side as much as possible.

  However, in this operation, the rack 17k and the pinion gear 15a may not be correctly engaged. FIG. 28A shows a state in which the food tray 17 and the lid member 16 once removed are set on the outer member 14. FIG. 28A shows a state in which the pair of racks 17k and the pinion gear 15a are engaged with each other with, for example, one tooth shifted from the left and right. For example, if the rack or pinion gear module is 1.5, this shift amount is about 4.7 mm because it is one tooth pitch.

  In this manner, when the lid member 16 is closed as shown in FIG. 28B while being shifted and meshed, the lid member 16 moves while being inclined with respect to the opening 14r. If the rack 14k and the pinion gear 15a are kept engaged until they are completely closed, the lid member 16 remains inclined and the opening 14r cannot be sealed.

  Therefore, in this embodiment, as shown in FIG. 28C, the rack 17k is not provided in the entire range of opening and closing. The rack 17k is disengaged from the pinion gear 15a in a state where the lid member 16 is completely closed and the packing 16p is in contact with the opening 14r. Thus, the packing 16p of the lid member 16 contacts the opening 14r when fully closed, regardless of the meshing between the rack 17k and the pinion gear 15a, so that the sealing can be ensured. In other words, in FIG. 28C, if the distance from the opening 14r of the outer member 14 to the pinion gear 15a is Lp, and the distance to the rack 17k is Lr, (Lp <Lr) may be satisfied.

<Rack length>
Furthermore, the range in which the rack 17k is provided and the method of removing the lid member 16 and the food tray 17 will be described with reference to FIG. The pinion gear 15 is provided in a second recess 14 w provided in the lower case 140 of the outer member 14. As described above, for example, water droplets condensed on the inner wall of the outer member 14 may accumulate in the second recess 14w and freeze. When freezing, the pinion gear 15 does not rotate, and therefore, if the rack 17k is engaged with the pinion gear 15a, there arises a problem that the lid member 16 and the food tray 17 are closed and cannot be opened.

  In the present embodiment, as described with reference to FIG. 28, the rack 17k does not mesh with the pinion gear 15a in the vicinity of the fully closed position of the lid member 16. That is, even if the pinion gear 15 does not rotate, the lid member 16 and the food tray 17 are integrally opened until the teeth of the rack 17k hit the pinion gear 15a.

  In this state, a gap gap is formed between the outer peripheral upper wall surface H1 of the reinforcing support H and the slope 14m of the upper surface opening support 14f of the outer member 14. Therefore, if the gap gap is larger than the meshing height hg of the teeth (gap> hg), the lid member 16 can be moved leftward in the drawing while the pinion gear 15a does not rotate. Therefore, the lid member 16 and the food tray 17 can be taken out. Then, the user can take out the frozen pinion gear 15a from the opening 14r, and scrape out the ice accumulated in the second recess 14w.

  In FIG. 29, the opening amount of the lid member 16 is (Lr-Lp) according to the notation of FIG. 28 (c), so that the gap (> hg) as shown in FIG. 29 is generated in this state. Is desirable.

  As described above, the pair of racks 17k provided on the bottom surface of the food tray 17 and the pair of pinion gears 15a provided on the bottom surface of the outer member 14 are not meshed when fully closed, but meshed in the middle of opening. Thus, when the lid member 16 is closed, the rack 17k and the pinion gear 15a are not meshed with each other, and the lid member 16 closely contacts the opening 14r, so that the opening 14r is reliably sealed and airtight. When opening and closing, the lid member 16 can move stably while maintaining parallelism. Furthermore, there is an effect that the food tray 17 and the lid member 16 can be removed even when the pinion gear 15 is frozen.

  Furthermore, an opening protrusion 14h extending from the vicinity of the opening 14r of the lower case 140 toward the rear wall 140d is provided, and the reaction member W 'supports the bottom surface of the food tray 17 and the tips of the lid member 16 and the food tray 17 hang down. Therefore, there is an effect that the food tray is firmly supported.

<Removal configuration of food tray and lid member>
Next, the structure which removes the food tray 17 from the cover member 16 is demonstrated in detail using FIGS. 30-41. FIG. 30 is a state diagram in which the lid member 16 is attached to the food tray 17. FIGS. 31 to 33 are partial cross-sectional views showing the operation of removing the lid member 16 from the food tray 17. 34 to 38 are partial cross-sectional views showing the operation of attaching the lid member 16 to the food tray 17. FIG. 39 shows a state in which the lid member 16 is attached to the food tray 17.

  In FIG. 30, as described above, the front wall 17e of the food tray 17 is connected to the concave portion 17f for arranging the reinforcing support portion H and the front wall 17e and the concave portion 17f along the reinforcing support portion H. A central side wall portion 17h is formed. As shown in FIGS. 12, 14 and 15, the food tray 17 is attached to the lid member 16 on the central side wall portion 17 h and the side walls 17 a and 17 b, and is linked to the opening / closing operation of the lid member 16. Two pairs of mounting claws 17t1 and 17t2 are formed.

  As described above, the two pairs of mounting claws 17t1 and 17t2 are formed in a semi-cylindrical shape with an opening at the bottom and a shape with one side extending downward, and a columnar shape provided on the lid member 16 The food tray 17 is fixed to the lid member 16 by engaging with the protrusions 16g1 and 16g2, and interlocked with the opening / closing operation of the lid member 16. Furthermore, an upwardly opening mounting claw 17t3 is provided on the top of the mounting claw 17t2, and a columnar protrusion 16g3 is provided upward by a predetermined distance U from the bottom surface 17t4 of the mounting claw 17t3.

  A locking rib 16j extends horizontally from the central portion 16c2 of the lid member 16 toward the concave portion 17f of the food tray 17. A stopper 17 n extends horizontally from the recess 17 f of the food tray 17 toward the lid member 16. The upper surface of the stopper 17n is in a positional relationship to be fitted with the lower surface of the locking rib 16j. By fitting the locking rib 16j and the stopper 17n, the lid member 16 is locked so that it cannot move downward with respect to the food tray 17. Therefore, the food tray 17 and the lid member 16 are fixed as shown in FIG.

  Next, the operation | movement which removes the cover member 16 from the food tray 17 is demonstrated. As shown in FIG. 31, when a force is applied in the direction of the arrow 18 by placing a finger on the center upper end of the concave portion 17f of the food tray 17, the concave portion 17f is deformed and the stopper 17n and the locking rib 16j are fitted. Come off. Then, the cover member 16 is not supported and is lowered by a distance U as indicated by an arrow 20 until the columnar protrusion 16g3 comes into contact with the bottom surface 17t4 of the mounting claw 17t3. The cylindrical protrusions 16g1 and 16g2 are disengaged from the mounting claws 17t1 and 17t2. Here, since the protrusion 16g3 of the lid member 16 is supported by the bottom surface 17t4 of the mounting claw 17t3, the lid member 16 does not come off the food tray 17 and falls unexpectedly.

  Next, as shown in FIG. 32, when the lid member 16 is rotated clockwise as indicated by an arrow, the lid member 16 is rotated around the columnar protrusion 16g3 and is continuously moved upward as shown in FIG. Thus, the lid member 16 can be removed from the food tray 17.

  Next, an example of the attachment procedure will be described with reference to FIGS. As shown in FIG. 34, in a substantially horizontal state with the packing 16p of the lid member 16 facing downward, the lid member 16 is lowered toward the food tray 17, and as shown in FIG. The outer peripheral upper wall surface H1 is hooked on the upper end 17f1 of the recess 17f of the food tray 17. Here, the distance r1 from the upper end 17f1 to the protrusion 16g3 and the dimension r2 from the mounting claw 17t3 to the upper end 17f1 are substantially equal. Therefore, as shown in FIG. 36, when the lid member 16 is subsequently rotated counterclockwise in the direction of the arrow about the upper end 17f1, the protrusion 16g3 is introduced into the groove of the mounting claw 17t3 as shown in FIG. If the width in the vicinity of the upper surface of the mounting claw 17t3 is widened, it becomes a guide when the protrusion 16g3 is introduced, and the operation is smoother and more suitable.

  Next, FIG. 38 shows a state in which the lid member 16 is rotated counterclockwise in the direction of the arrow until the projection 16g3 serves as a fulcrum. The lid member 16 is in a state where the protrusion 16g3 is placed on the bottom surface 17t4 of the mounting claw 17t3. Next, as shown in FIG. 39, when the lid member 16 is moved in the direction of the arrow 21 from below, the protrusions 16g1 and 16g2 are fitted into the attachment claws 17t1 and 17t2, respectively. When the stopper inclined surface 17p is pushed by the locking rib 16j, the concave portion 17f is once bent as indicated by a broken line 17f 'and then restored by elasticity, so that the upper surface of the stopper 17n is connected to the lower surface of the locking rib 16j. It becomes the positional relationship to fit. The state shown in FIG. 39 is the same as that shown in FIG. 30, and the lid member 16 and the food tray 17 are fixed to each other to be in the state shown in FIG.

  With the above configuration, only the food tray 17 can be easily detached and reattached, so that it is possible to provide an easy-to-use refrigerator that can easily wash only the food tray 17, for example.

<Spindle deformation prevention>
As previously described with reference to FIGS. 38 to 39, the lid member 16 is moved relative to the food tray 17 in the direction of the arrow 21 from below to fix the lid member 16 and the food tray 17 to each other. FIG. 40 shows an example of an operation of holding the substantially central portion of the lid member 16 provided with the handle 26 at this time. In this embodiment, a fingertip other than the thumb is hooked on a protrusion 16t provided integrally with the lid member 16 in the vicinity below the support shaft 35s, and a force is applied in the direction of the arrow 21. Here, if there is no protrusion 16t, a fingertip other than the thumb may be hung on the support shaft 35s of the valve opening / closing member 35. Then, the force in the direction of the arrow 21 is applied to the support shaft 35s, and the support shaft 35s is deformed to make it difficult for the force to enter. In addition, if the force is applied forcefully, the support shaft 35s may be damaged. In this embodiment, since the protrusion 16t on which the fingertip hangs is provided near the lower portion of the support shaft 35s, it is easy to apply a force when the lid member 16 and the food tray 17 are fixed to each other, and the support shaft 35s is not deformed or damaged. Therefore, it is possible to realize a method of fixing the lid member 16 and the food tray 17 with high reliability.

<Effect>
As in the above-described embodiments, according to the present invention, the resin molded product obtained by dividing the outer shell member 14 into upper and lower parts is hermetically sealed, and further formed into a dome shape that protrudes outward, thereby expanding the internal volume. It is possible to secure strength. In addition, since both the upper case 141 and the lower case 140 can be molded from resin, there is an effect that the outer member 14 can be configured at low cost.

  In particular, when sealing while maintaining airtightness, it is preferable to weld the connecting portion between the upper case and the lower case, which eliminates the need for seal parts such as rubber packing, improves reliability, and can be configured at a lower cost. is there.

  Further, the lid member and the food tray are fixed to each other and opened and closed, and a rack provided on the bottom surface of the food tray and a pair of pinion gears fitted in a recess provided on the inner bottom surface of the outer shell member are engaged with each other. Thereby, in order to open and close the lid member 16 and the food tray 17 forward and backward, it is not necessary to provide a rail member or the like. Furthermore, there is no need to provide parts such as a support shaft to support the pinion gear, and the lid member 16 and the food tray 17 can be opened and closed stably with a simple configuration while being kept parallel.

  Furthermore, the inner periphery of the upper case 141 is an extended portion 142a that extends further below the V packing 147 and below the upper end of the inner periphery of the lower case. As a result, the condensed water droplets hang down along the inner wall, accumulate at the lower end of the extending portion 142a, and drop onto the inner wall of the lower case 140 without entering the V packing 147 side. That is, there is an effect that water droplets are surely dropped from the inner wall of the upper case 141 to the inner wall of the lower case 140.

  Furthermore, a first recess for accumulating condensed water droplets or moisture or liquid foreign matter spilled outside the food case is provided in the center of the bottom surface of the lower case and the inside of the outer member provided with a pinion gear. The central part in the longitudinal direction of the second recess provided on the bottom surface is made more concave than both end sides. Thereby, there is an effect that the amount of moisture or liquid foreign matter stored until the moisture or liquid foreign matter affects the rotation of the pinion gear can be increased.

  Furthermore, since the first concave portion and the second concave portion are provided above the lowermost end of the lower case 140, it is not necessary to make the heat insulating partition wall thin by the first concave portion and the second concave portion, thereby A refrigerator with excellent properties can be obtained.

  Further, an opening protrusion 14h extending from the vicinity of the opening 14r of the lower case 140 toward the rear wall 140d is provided, and the bottom surface of the food tray 17 is supported by the reaction force W ′ to prevent the lid member 16 and the food tray 17 from tipping down. Therefore, there is an effect that the food tray is firmly supported.

  In addition, since only the food tray can be easily detached and attached from the lid member, for example, it is possible to provide an easy-to-use refrigerator in which only the food tray can be easily washed. Furthermore, it is easy to apply force when the lid member 16 and the food tray 17 are fixed to each other, and the deformation and breakage of the support shaft 35s can be prevented, thereby realizing a highly reliable method for fixing the lid member 16 and the food tray 17. .

  Moreover, since the recessed part which accommodates the rack and pinion mechanism part which is a synchronizing means does not become convex from the lower side of a decompression chamber, it is not necessary to make a heat insulation wall thin, and the refrigerator excellent in heat insulation can be obtained.

DESCRIPTION OF SYMBOLS 1 Refrigerator body 2 Refrigeration room 3 Ice making room 4 Quick freezing room 5 Freezing room 6 Vegetable room 12 Vacuum pump 13 Decompression room (storage room, gas control room)
14 Outer shell (storage container)
14z 1st recessed part 14w 2nd recessed part 15 Pinion gear 15b Connecting shaft (synchronizing means)
16 Decompression chamber lid (lid member)
17 Food tray (withdrawal container)
140 Lower case (first outer member)
141 Upper case (second outer member)

Claims (4)

A storage chamber composed of a first outer member having a first opening and a second opening, a second outer member closing the second opening, and a lid member for opening and closing the first opening With
The opening edge of the second opening of the first outer member is formed to be inclined rearward from the first opening, and the lower surface of the storage chamber has a curved shape protruding downward. A refrigerator having a first recess recessed from the inner surface to the outer surface from the center of the lower surface. The storage container synchronizes the drawer container connected to the lid member, a pair of rack gears provided on the lower surface of the drawer container in the front-rear direction, a pair of pinion gears that rotate in mesh with the rack gear, and the pair of pinion gears. Synchronization means
A second recess is provided on the lower surface of the storage chamber so as to be parallel to the first opening for rotatably supporting the pinion gear, and the second recess has a central portion rather than left and right end portions. The refrigerator according to claim 1, wherein the refrigerator has a shape recessed from the inner surface to the outer surface.   The refrigerator according to claim 1 or 2, wherein the first recess and the second recess are provided above a lower end of the storage chamber. In the refrigerator having a storage space, the storage space includes a box-shaped storage container, the storage container having a first opening for taking in and out stored items, a lid member for opening and closing the first opening, and the lid A seal member that is provided between the member and the first opening with which the lid member abuts and suppresses gas movement between the lid member and the first opening,
A first outer member having an upper surface, a lower surface, left and right side surfaces, and a rear surface facing the first opening, and having a second opening formed in the upper portion, and a second outer member closing the second opening And the inner periphery of the second opening of the second outer member has a cross section extending downward from the upper end of the first opening.

Images