JP2019066142A - Steam generating device and heating cooker - Google Patents

Abstract

To provide a steam generating device and a heating cooker that can enhance accuracy of water level detection, and can reduce water and scale remaining on a bottom part of a cover.SOLUTION: The steam generating device comprises a water level sensor for detecting a water level in a steam generating container, and a cover (106). The cover (106) comprises a first wall part (161) arranged on one side of the water level sensor and provided with a first through hole (172), a second wall part (162) arranged on another side of the water level sensor and provided with a second through hole (173), and a bottom part (160) arranged below the water level sensor. An upper surface of the bottom part (160) of the cover (106) includes an inclined surface (181) inclined with respect to a horizontal direction so that the side of the second wall part (162) is lower than the side of the first wall part (161).SELECTED DRAWING: Figure 12

Description

  The present invention relates to a steam generator and a heating cooker.

  Conventionally, as a steam generating apparatus, a cylindrical partition dividing the inside of a container, a water storage chamber provided inside the partition and an electrode rod for detecting water level and a steam delivery pipe, and provided outside the partition And an evaporation chamber disposed such that the heating element is submerged in water (see, for example, JP-A-2000-266302 (Patent Document 1)). In this steam generator, the water supplied into the water storage chamber from the lower side of the container flows into the evaporation chamber through a water passage provided below the partition wall. At this time, the heating element heats the water in the evaporation chamber to generate steam.

JP 2000-266302 A

  By the way, in the above-mentioned conventional steam generating device, when the cylindrical partition is changed to a bottomed cylindrical cover and a through hole is provided on the side of the bottomed cylindrical cover, the water in the evaporation chamber is boiled Since the amount of boiling bubbles generated in the vicinity of the electrode rod decreases, it is possible to improve the accuracy of water level detection by the electrode rod.

  However, when the bottomed cylindrical cover is used, even if the water in the water storage chamber is discharged, there is a problem that water or scale tends to remain on the bottom of the bottomed cylindrical cover.

  Therefore, an object of the present invention is to provide a steam generator and a heating cooker which can increase the accuracy of water level detection and reduce water and scale remaining on the bottom of the cover.

The steam generator according to one aspect of the present invention is
A steam generating container for storing water inside;
A heater for heating water in the steam generation container;
A water level sensor for detecting the water level in the steam generation container;
A first wall portion disposed on one side of the water level sensor and provided with a first through hole, and a second wall portion disposed on the other side of the water level sensor and provided with a second through hole And a cover having a bottom disposed below the water level sensor,
The upper surface of the bottom of the cover includes an inclined surface which is inclined with respect to the horizontal direction such that the second wall side is lower than the first wall side.

The heating cooker according to one aspect of the present invention is
Any one of the steam generating devices described above;
And a heating chamber to which the steam from the steam generator is supplied.

  In the steam generating device according to the present invention, the inclined surface including the upper surface of the bottom of the cover is inclined with respect to the horizontal direction so that the second wall side is lower than the first wall side. The accuracy of detection can be increased, and the water and scale remaining on the bottom of the cover can be reduced.

  The heating cooker according to the present invention can reduce the scale generated in the steam generator by providing the steam generator, so that sanitary steam can be supplied to the heating chamber.

It is a schematic front view at the time of door closing of the cooking-by-heating machine of a 1st embodiment of this invention. It is a schematic front view at the time of the door opening of the said heating cooker. It is a schematic diagram for demonstrating the structure of the principal part of the said heating cooker. It is a top view of the steam generator of the above-mentioned cooking-by-heating machine. It is a front view of the above-mentioned steamy generator. It is sectional drawing of the VI-VI line arrow of FIG. It is a perspective view of a cover for water level detection chambers of the above-mentioned steamy generator. It is a side view of one side of the cover for the above-mentioned water level detection room. It is the other side view of the cover for the above-mentioned water level detection room. It is a front view of the cover for the said water level detection chamber. It is a top view of the cover for the said water level detection chamber. It is sectional drawing of the XII-XII arrow line view of FIG. It is sectional drawing of the cover for water level detection chambers of 2nd Embodiment of this invention. It is a top view of the cover for water level detection chambers of a 3rd embodiment of this invention.

  Hereinafter, the steam generator of the present invention and the heating cooker using the same will be described in detail by the illustrated embodiments.

First Embodiment
FIG. 1: is a schematic front view at the time of the door closing of the heating cooker using the steam generator 100 (shown in FIG. 3) of 1st Embodiment of this invention. Moreover, FIG. 2 is a schematic front view at the time of the door opening of the said heating cooker.

  The heating cooker according to the first embodiment is, as shown in FIGS. 1 and 2, a rectangular parallelepiped main body casing 1 and a heating chamber 2 provided in the main body casing 1 and having an opening 2a on the front side, The door 3 which opens and closes the opening part 2a of the heating chamber 2, The magnetron (not shown) which supplies a microwave in the heating chamber 2 in which a foodstuff is accommodated is provided.

  An exhaust duct 5 is provided at the rear of the upper surface of the main body casing 1. Further, the dew receptor 6 is detachably attached to the lower part of the front surface of the main body casing 1. The dew receiver 6 is located below the door 3 and can receive water droplets from the rear surface (surface on the heating chamber 2 side) of the door 3. In addition, a water supply tank 26, which will be described later, is also detachably attached to a lower portion of the front surface of the main body casing 1.

  The door 3 is attached to the front side of the main body casing 1 so as to be pivotable about the lower side. A heat-resistant transparent outer glass 7 is provided on the front surface of the door 3 (surface opposite to the heating chamber 2). Further, the door 3 has a handle 8 located on the upper side of the outer glass 7 and an operation panel 9 provided on the right side of the outer glass 7.

  The operation panel 9 has a color liquid crystal display unit 10 and a button group 11. The button group 11 includes a cancel key 12 which is pressed when heating is stopped midway, and a start key 13 which is pressed when heating is started. In addition, the operation panel 9 is provided with an infrared light receiving unit 14 that receives infrared light from a smartphone or the like.

  An object to be heated 15 is accommodated in the heating chamber 2. Further, the metal cooking trays 91 and 92 (shown in FIG. 3) can be taken in and out of the heating chamber 2. On the inner surfaces of the left side portion 2b and the right side portion 2c of the heating chamber 2, upper shelf supports 16A and 16B for supporting the cooking tray 91 are provided. Further, on the inner surface of the right side portion 2c and the left side portion 2b of the heating chamber 2, lower shelf receivers 17A and 17B for supporting the cooking tray 92 are provided to be positioned lower than the upper shelf receivers 16A and 16B. .

  FIG. 3: is a schematic diagram for demonstrating the structure of the principal part of the said heating cooker. In FIG. 3, the heating chamber 2 is shown as viewed from the left side. In addition, in FIG. 3, 3 is a door, 6 is a dew receptor.

  The heating cooker includes the circulation duct 18, the circulation fan 19, the upper heater 20, the middle heater 21, the lower heater 22, the circulation damper 23, the tube pump 25, the water supply tank 26, and the steam generator 100. And have. Each of the upper heater 20, the middle heater 21 and the lower heater 22 is, for example, a sheathed heater.

  An upper portion 2 e of the heating chamber 2 is continuous with the rear portion 2 d of the heating chamber 2 via an inclined portion 2 f which is inclined with respect to the horizontal direction. In the inclined portion 2f, a plurality of suction ports 27 are provided to face the circulation fan 19 (see FIG. 2). Further, a plurality of upper outlets 28 are provided in the upper portion 2 e of the heating chamber 2. In addition, a plurality of first rear air outlets 29, second rear air outlets 30, and third rear air outlets 31 are provided in the rear portion 2d of the heating chamber 2 (see FIG. 2). In addition, only three suction ports 27 are shown in FIG. Further, only one each of the first rear air outlet 29, the second rear air outlet 30, and the third rear air outlet 31 is shown in FIG.

  The circulation duct 18 is in communication with the inside of the heating chamber 2 through the suction port 27, the upper air outlet 28, and the first to third rear air outlets 29-31. The circulation duct 18 is provided from the upper side to the rear side of the heating chamber 2 and extends to have an inverted L shape. Further, the width in the left-right direction of the circulation duct 18 is set narrower than the width in the left-right direction of the heating chamber 2.

  The circulation fan 19 is a centrifugal fan and is driven by a circulation fan motor 56. When the circulation fan motor 56 drives the circulation fan 19, air and saturated vapor in the heating chamber 2 are drawn into the circulation duct 18 from the suction port 27 and flow radially outward of the circulation fan 19.

  The circulation damper 23 is rotatably provided in the circulation duct 18 and between the middle heater 21 and the lower heater 22. The rotation of the circulation damper 23 is performed by a circulation damper motor (not shown).

  The steam generating apparatus 100 is formed of, for example, a metal such as an aluminum alloy, and covers the steam generating container 101 having the opening 101a on the upper side, and the opening 101a of the steam generating container 101 to cover a heat resistant resin (such as PPS (polyphenylene sulfide). ) And a steam generation heater 103 formed of a sheathed heater cast in the bottom portion 101b of the steam generation container 101 (see FIGS. 4 to 6). Water from the water supply tank 26 is accumulated on the bottom portion 101 b of the steam generation container 101, and the steam generation heater 103 heats the water via the steam generation container 101. Then, saturated steam generated by heating by the steam generation heater 103 flows through the resin steam tube 35 and the metal steam tube 36, and is supplied into the heating chamber 2 through the plurality of steam supply ports 37. (See Figure 2). In FIG. 3, only one steam supply port 37 is shown. The steam generation heater 103 is an example of a heater.

  Further, saturated vapor in the heating chamber 2 is sent to the upper heater 20, the middle heater 21 and the lower heater 22 by the circulation fan 19 and heated by the upper heater 20, the middle heater 21 and the lower heater 22 to be 100 ° C. or higher. Become superheated steam.

  Further, a water level sensor 105 including a pair of electrode rods 105 a and 105 b is attached to the lid 102. Based on whether or not the electrode rods 105a and 105b are in the conductive state, it is determined whether the water level on the bottom portion 101b of the steam generation container 101 has reached a predetermined water level.

  The tube pump 25 squeezes the elastically deformable water supply and drainage tube 40 made of silicone rubber or the like with a roller (not shown), and the water in the water supply tank 26 flows to the steam generating device 100 depending on the driving direction of the roller. The water in the steam generator 100 is flowed to the water supply tank 26.

  The water supply tank 26 has a water supply tank main body 41 and a communication pipe 42. One end of the communication pipe 42 is located inside the water supply tank main body 41, and the other end of the communication pipe 42 is located outside the water supply tank 26. When the water supply tank 26 is accommodated in the tank cover 43, the other end of the communication pipe 42 is connected to the water supply and drainage tube 40 via the tank joint portion 44. That is, the inside of the water supply tank main body 41 communicates with the inside of the steam generating apparatus 100 through the communication pipe 42 and the like.

  FIG. 4 is a view of the steam generator 100 as viewed from above. Moreover, FIG. 5 has shown the side view of the front of the steam generator 100. As shown in FIG. In FIGS. 4 and 5, the same components as those in FIG. 3 are given the same reference numerals as those in FIG.

  As shown in FIGS. 4 and 5, the steam generating apparatus 100 includes a heat insulating cover 104 formed so as to cover the steam generating container 101 and at an interval from the steam generating container 101. The heat insulating cover 104 is made of, for example, a heat resistant resin such as PPS (polyphenylene sulfide) resin, and is fixed to the flange portion 102 b of the lid portion 102. The heat insulating cover 104 may not be a heat resistant resin, and may be a resin which does not deform by heat of about 100.degree.

  Further, the steam generation heater 103 is a U-shaped heater, and extends from one longitudinal direction of the bottom portion 101 b of the steam generation container 101 to the other.

  4 and 5, reference numeral 102a denotes a main body of the lid 102, 108 denotes a water outlet connection, and 113 denotes a steam outlet connection.

  FIG. 6 is a view showing a cross section viewed from line VI-VI of FIG. 4. In FIG. 6, the same components as those in FIGS. 3 to 5 are denoted by the same reference numerals as those in FIGS. 3 to 5.

  The lid portion 102 has a main body portion 102 a, a flange portion 102 b provided at the lower end of the main body portion 102 a, and an insertion portion 102 c extending downward from the lower surface of the flange portion 102 b. The main body portion 102a, the flange portion 102b, and the insertion portion 102c are integrally formed of a heat resistant resin.

  The insertion portion 102c of the lid portion 102 is inserted on the inner peripheral side of the opening portion 101a of the steam generation container 101, and an annular portion is formed between the inner peripheral side of the steam generation container 101 and the outer peripheral surface of the insertion portion 102c of the lid portion 102. Is sealed by the seal member 111 of FIG. The annular seal member 111 is made of a heat resistant resin such as silicone rubber. The inner peripheral surface of the steam generating container 101 is coated with silicon.

  A water level detection chamber cover 106 is disposed in a steam generation space P1 formed by the steam generation container 101 and the lid portion 102. A water level detection chamber P2 is formed by a part of the lid portion 102 and the water level detection chamber cover 106, and the electrode rods 105a and 105b of the water level sensor 105 are accommodated in the water level detection chamber P2. The water level detection chamber cover 106 is an example of a cover.

  Further, on the lower surface of the step portion 112 of the lid portion 102, a partition wall 109 for partitioning the electrode rods 105a and 105b is provided upright.

  Further, the stepped portion 112 of the lid portion 102 is provided with a tubular water supply / discharge port connecting portion 108 which penetrates the stepped portion 112. Furthermore, a water supply / drainage pipe 107 extending from the water supply / discharge port connection portion 108 of the step portion 112 of the lid portion 102 to the lower side in the steam generation container 101 and continuing to the water supply / discharge port connection portion 108 is provided. The water supply to the inside of the steam generation container 101 and the drainage from the inside of the steam generation container 101 are performed through the water supply / discharge port 107 a at the lower end of the water supply / discharge pipe 107. The water supply and drainage port 107 a is opened in the vicinity of the bottom portion 101 b in the steam generation container 101. One end of a water supply and drainage tube 40 is connected to the water supply and discharge port connecting portion 108.

  Further, a convex portion 102 d is provided on the upper side of the main body portion 102 a of the lid portion 102. A steam outlet connection portion 113 having a steam outlet 113a is provided at the tip of the convex portion 102d. Note that one end of the steam tube 35 is connected to the steam outlet connection portion 113.

  Further, the steam generating apparatus 100 includes a steam generating container in a region facing one shoulder (in the right side of the protrusion 102d shown in FIG. 6) in the vicinity of the protrusion 102d in the lid 102 and below the protrusion 102d. A boiling water blocking wall 110 is provided to block boiling water from 101. The boiling water blocking wall 110 is bent so that the cross-sectional shape becomes a U-shape.

  In addition, the curved portion of the steam generation heater 103 is positioned on one side of the steam generation apparatus 100, and the connection terminal 103a (power supply unit) of the steam generation heater 103 is one side of the steam generation apparatus 100. Most of the heat generating portion 103b of the steam generation heater 103 is embedded in the bottom portion 101b of the steam generation container 101 so as to be located on the side (see FIG. 4). The connection terminal 103a is an example of a terminal portion.

  Moreover, in the steam generation container 101, a part of the bottom in the steam generation container 101 is inclined along the longitudinal direction in which the heater 103 for steam generation extends. Thereby, it is possible to collect water at the water outlet / drain port 107a which is a drain port at the time of drainage.

  Further, the heat insulating cover 104 has an opening 104 a for leading the connection terminal 103 a of the steam generation heater 103 cast in the steam generation container 101 to the outside.

  A thermal fuse 130 is attached to the side surface of the steam generation container 101 near the connection terminal 103 a of the steam generation heater 103. The thermal fuse 130 cuts off the voltage applied to the connection terminal 103 a of the steam generation heater 103 when the steam generation container 101 reaches an abnormal temperature.

  In addition, a temperature sensor 140 for steam generation is attached to the central portion of the bottom portion 101 b of the steam generation container 101.

  FIG. 7 is a view of the water level detection chamber cover 106 of the steam generator 100 shown in FIG. 6 as viewed obliquely from above.

  The water level detection chamber cover 106 has a bottom portion 160, and a first wall portion 161, a second wall portion 162, a third wall portion 163, and a fourth wall portion 164 erected on the periphery of this portion. There is. The first wall portion 161 and the second wall portion 162 face each other. In addition, the third wall 163 faces the fourth wall 164.

  FIG. 8 is a view of the water level detection chamber cover 106 as viewed from one side. In FIG. 8, the same components as those in FIG. 7 are assigned the same reference numerals as those in FIG.

  The first wall portion 161 of the water level detection chamber cover 106 is erected on the end of the bottom portion 160 opposite to the connection terminal 103a (the end portion of the bottom portion 160 on the steam outlet 113a side) (FIG. 6) reference). The upper end portion of the first wall portion 161 is provided with a mounting portion 165 which protrudes toward the opposite side to the second wall portion 162. The water level detection chamber cover 106 is attached to the lid 102 by tightening a screw inserted into the through hole 166 (shown in FIG. 7) of the attachment portion 165. At this time, the first wall portion 161 is disposed on one side of the water level sensor 105.

  Further, a first upper through hole 171 having a substantially rectangular shape in a side view is provided near the attachment portion 165 of the first wall portion 161 and on the lower side, and the steam generation space P1 It communicates with the water level detection chamber P2. Thereby, it is possible to reduce the difference between the water level in the water level detection chamber P2 and the water level outside the water level detection chamber P2.

  Further, in the vicinity of the bottom portion 160 of the first wall portion 161, a first lower through hole 172 having a substantially rectangular shape in a side view is provided. When water is stored in the steam generation container 101, the water flows from the first lower through hole 172 into the water level detection chamber P2. The first lower through hole 172 is an example of a first through hole.

  FIG. 9 is a view of the water level detection chamber cover 106 as viewed from the other side. In FIG. 9, the same components as those in FIGS. 7 and 8 have the same reference numerals as those in FIGS. 7 and 8.

  The second wall portion 162 of the water level detection chamber cover 106 is provided upright on the end portion of the bottom portion 160 on the connection terminal 103 a side (the end portion of the bottom portion 160 opposite to the steam outlet 113 a). The length of the second wall 162 in the vertical direction is shorter than the length of the first wall 161 in the vertical direction. Further, the upper end of the second wall portion 162 is located below the upper end of the first wall portion 161. Further, when the water level detection chamber cover 106 is attached to the lid portion 102, the first wall portion 161 is disposed on the other side of the water level sensor 105.

  Further, in the vicinity of the bottom portion 160 of the second wall portion 162, a second through hole 173 having a substantially rectangular shape in a side view is provided. The length of the second through hole 173 in the vertical direction is longer than the length of the first lower through hole 172 in the vertical direction. Thus, the opening area of the second through hole 173 is larger than the opening area of the first lower through hole 172. Further, similarly to the first lower through hole 172, when water is stored in the steam generation container 101, the water flows from the second through hole 173 into the water level detection chamber P2.

  The electrode rods 105a and 105b are disposed such that the lower ends of the electrode rods 105a and 105b are located above the first lower through holes 172 and the second through holes 173.

  FIG. 10 is a front view of the water level detection chamber cover 106. In FIG. 10, the same components as those in FIGS. 7 to 9 have the same reference numerals as those in FIGS. 7 to 9.

  As shown in FIGS. 7 and 10, notches 163a and 164a are provided in the third and fourth wall portions 163 and 164 of the water level detection chamber cover 106, respectively. Thus, water can easily move between the water level detection chamber P2 and the water level detection chamber P2.

  FIG. 11 is a top view of the water level detection chamber cover 106. 12 is a cross-sectional view as viewed from line XII-XII in FIG. In FIGS. 11 and 12, the same components as those in FIGS. 7 to 10 have the same reference numerals as those in FIGS. 7 to 10.

  As shown in FIGS. 11 and 12, a drain port 174 is provided in the bottom portion 160 of the water level detection chamber cover 106. The drainage port 174 is located on the second wall portion 162 side and communicates with the second through hole 173 of the second wall portion 162. In addition, a pair of water guide portions 167A and 167B protruding downward from the bottom portion 160 is provided at the peripheral edge portion of the drainage port 174.

  Further, when the water level detection chamber cover 106 is attached to the lid portion 102, the drainage port 174 is formed so that the drainage port 174 and the water level sensor 105 do not face each other in the vertical direction. In other words, when the water level detection chamber cover 106 is attached to the lid 102, the drainage port 174 is not located below the water level sensor 105.

  The upper surface of the bottom portion 160 of the water level detection chamber cover 106 includes a first inclined surface 181 as an example of an inclined surface, and second and third inclined surfaces 182 and 183 provided so as to sandwich the first inclined surface 181. Contains. The first inclined surface 181, the second inclined surface 182, and the third inclined surface 183 are each inclined with respect to the horizontal plane.

  More specifically, each of the first inclined surface 181, the second inclined surface 182, and the third inclined surface 183 has a trapezoidal shape in a plan view. The leg side on the third wall portion 163 side of the first inclined surface 181 is the leg side on the first wall portion 161 side of the second inclined surface 182. On the other hand, the leg side of the first inclined surface 181 on the fourth wall portion 164 side is the leg side of the third inclined surface 183 on the first wall portion 161 side. That is, the first inclined surface 181 shares one leg side with the second inclined surface 182, and shares the other leg side with the third inclined surface 183.

  Further, the first inclined surface 181 is formed such that the end on the second wall portion 162 side is lower than the end on the first wall portion 161 side. The second inclined surface 182 is formed such that the end on the drainage port 174 side is lower than the end on the third wall portion 163 side. Similar to the second inclined surface 182, the third inclined surface 183 is also formed such that the end on the side of the drainage port 174 is lower than the end on the side of the fourth wall portion 164.

  The water on the bottom portion 160 of the water level detection chamber cover 106 also flows toward the drainage port 174 by the first inclined surface 181, the second inclined surface 182, and the third inclined surface 183.

  The water level sensor 105 and the water level detection chamber cover 106 are disposed on the connection terminal 103 a side of the steam generation heater 103.

  In the heating cooker of the above configuration, when superheated steam or saturated steam is used for the heating and cooking of the object to be heated 15, first, whether or not the water level in the steam generating container 101 has reached a predetermined water level using the water level sensor 105 Determine At this time, if it is determined that the water level in the steam generation container 101 has not reached the predetermined water level, the tube pump 25 is turned on to supply water into the steam generation container 101. Thus, water flows into the water level detection chamber P2 from the first lower through holes 172 of the first wall portion 161 and the second through holes 173 of the second wall portion 162.

  Thereafter, when it is determined that the water level in the steam generation container 101 has reached the predetermined water level, the tube pump 25 is turned off, and the steam generation heater 103 is turned on to boil the water in the steam generation container 101. As a result, steam is generated in the steam generation space P1 between the steam generation container 101 and the lid portion 102. At this time, since the bottom portion 160 of the water level detection chamber cover 106 is located below the water level sensor 105, boiling bubbles generated in the vicinity of the water level sensor 105 can be reduced. Therefore, the accuracy of water level detection by the water level sensor 105 can be enhanced.

  Further, when the water level in the steam generation container 101 falls and the water in the steam generation space P1 flows out of the steam generation space P1, the upper surface of the bottom portion 160 of the water level detection chamber cover 106 includes the first inclined surface 181. The water on the bottom portion 160 of the water level detection chamber cover 106 flows from the side of the first lower through hole 172 of the first wall portion 161 to the side of the second through hole 173 of the second wall portion 162. As a result, the drainage property on the bottom portion 160 of the water level detection chamber cover 106 is improved, so water remaining on the bottom portion 160 of the water level detection chamber cover 106 can be reduced.

  Further, since water remaining on the bottom portion 160 of the water level detection chamber cover 106 can be reduced, the scale generated on the bottom portion 160 of the water level detection chamber cover 106 can also be reduced.

  If a large amount of scale is generated on the bottom portion 160 of the water level detection chamber cover 106, the large scale causes the opening area of the first lower through hole 172, the second through hole 173, or the drainage port 174 to decrease. It will As a result, it is difficult for water to flow between the inside of the steam generation space P1 and the outside of the steam generation space P1, and the accuracy of water level detection by the water level sensor 105 may be lowered.

  In addition, since the bottom portion 160 of the water level detection chamber cover 106 is provided with the drainage port 174, the drainage performance on the bottom portion 160 of the water level detection chamber cover 106 can be further improved.

  Further, since the drainage port 174 communicates with the second through hole 173, it is possible to suppress that the water film can be formed into the drainage port 174 by surface tension.

  In addition, since relatively low end portions of the first inclined surface 181, the second inclined surface 182, and the third inclined surface 183 are disposed around the drainage port 174, the first inclined surface 181, the second inclined surface The inclined surface 182 and the third inclined surface 183 can guide water on the bottom portion 160 of the water level detection chamber cover 106 to the drainage port 174.

  In addition, since the water guide portions 167A and 167B protruding downward from the bottom portion 160 are provided on the peripheral edge portion of the drain port 174, the water in the drain port 174 is actively used by the water guide portions 167A and 167B. It can flow downward. As a result, it is possible to enhance the effect of suppressing that the water film can be formed in the drainage port 174 by surface tension.

  Further, since the water level sensor 105 is disposed so as not to face the drainage port 174 in the vertical direction, the possibility that boiling bubbles reach the vicinity of the water level sensor 105 rising through the drainage port 174 can be reduced. .

  Further, in the steam generation container 101, the temperature of the region on the connection terminal 103a side of the heater 103 for steam generation is lower than the temperature of the other regions. Therefore, since the water level sensor 105 is disposed in the region of the steam generation container 101 and on the connection terminal 103 a side of the heater 103 for steam generation, boiling bubbles generated in the vicinity of the water level sensor 105 can be reduced.

  In addition, after boiling the water in the steam generation container 101, if the water in the steam generation container 101 is taken out of the steam generation apparatus 100 via the water supply and drainage pipe 107 when the water temperature is not fully lowered, the first inclination Since the first inclined surface 181 is inclined so that the connection terminal 103a side of the surface 181 is lower than the opposite side of the first inclined surface 181 with the connection terminal 103a, in a region where the water convection is relatively strong Water on the bottom 160 of the water level detection chamber cover 106 can be guided. Therefore, the drainage efficiency of water on the bottom portion 160 of the water level detection chamber cover 106 can be increased.

  On the other hand, even if the water on the bottom portion 160 of the water level detection chamber cover 106 is to flow on the opposite side to the connection terminal 103a, the convection of water is compared on the opposite side to the connection terminal 103a in the steam generation container 101. Because water is intense, water on the bottom portion 160 of the water level detection chamber cover 106 does not easily flow out of the water level detection chamber P2. That is, the drainage efficiency of water on the bottom portion 160 of the water level detection chamber cover 106 does not increase.

  Further, since the second through hole 173 and the drainage port 174 are disposed on the water supply and drainage pipe 107 side in the steam generation container 101, the drainage efficiency of the water supply and drainage pipe 107 can be improved.

  Moreover, since such a steam generating device 100 is mounted on the heating cooker, hygienic steam can be supplied to the heating chamber 2.

  In the first embodiment, the water level detection chamber cover 106 is provided separately from the lid portion 102. However, the water level detection chamber cover 106 may be provided integrally with the lid portion 102.

  In the first embodiment, the lid 102 made of a heat-resistant resin is used, but for example, a lid made of a non-heat-resistant resin may be used. In this case, for example, the space between the lid and the steam generation vessel 101 may be thermally insulated by a heat insulating member.

  In the first embodiment, the steam generation heater 103 is embedded in the bottom portion 101 b of the steam generation container 101, but may not be embedded in the bottom portion 101 b of the steam generation container 101. In this case, the heater for steam generation may be arranged to be in direct or indirect contact with the outer surface of the bottom 101 b of the steam generation vessel 101.

  In the first embodiment, the steam generation heater 103 is formed of one U-shaped heater, but may be formed of two linear heaters.

  In the first embodiment, the steam generation container 101 is a container having a rectangular shape in a plan view, but may be a container having a circular shape in a plan view.

  In the first embodiment, the water guides 167A and 167B are provided on the peripheral edge of the drainage port 174. However, only one of the water guides 167A and 167B may be provided. A shaped water guide may be provided.

  In the first embodiment, the opening 101 a of the steam generating container 101 is covered by the lid 102, but may not be covered by the lid 102. That is, the steam generating apparatus 100 may not include the lid 102.

Second Embodiment
FIG. 13: is sectional drawing which cut | disconnected the cover 2106 for water level detection chambers of the steam generator with which the heating cooker of 2nd Embodiment of this invention is provided in a perpendicular surface. In FIG. 13, the same components as those in FIG. 12 have the same reference numerals as those in FIG.

  The heating cooker according to the second embodiment has the same configuration as the heating cooker according to the first embodiment except for the water level detection chamber cover 2106 of the steam generator.

  The water level detection chamber cover 2106 has a first wall portion 2161 and a bottom portion 2160 whose shapes are different from those of the first wall portion 161 and the bottom portion 160 in the first embodiment.

  The inner surface of the first wall portion 2161 includes an inclined surface 2184 which is inclined with respect to the vertical direction. The inclined surface 2184 is formed such that the lower end is located closer to the second wall portion 162 than the upper end.

  Further, a first lower through hole 2172 is provided near the bottom 2160 of the first wall 2161. The first lower through hole 2172 is slightly longer than the first lower through hole 172 in the first embodiment, and the shape in side view is the same as the shape of the first lower through hole 172.

  The top surface of the bottom 2160 includes a first inclined surface 2181 as an example of the inclined surface. The first inclined surface 2181 is inclined with respect to the horizontal plane, similarly to the first inclined surface 181 of the first embodiment.

  In the heating cooker of the above configuration, the inner surface of the first wall portion 2161 includes the inclined surface 2184, and the lower end of the inclined surface 2184 is positioned closer to the second wall portion 162 than the upper end of the inclined surface 2184. The water that has fallen from the inner surface of the portion 2161 onto the bottom portion 2160 can be forcefully flowed to the second wall portion 162 side. Therefore, the water is easily discharged from the second through hole 173 to the outside of the water level detection chamber cover 2106.

Third Embodiment
FIG. 14: is the figure which looked at the cover 3106 for water level detection chambers of the steam generator with which the heating cooker of 3rd Embodiment of this invention is equipped from upper direction. In FIG. 14, the same components as those in FIG. 11 are denoted by the same reference numerals as those in FIG.

  The heating cooker of the third embodiment has the same configuration as the heating cooker of the first embodiment except for the water level detection chamber cover 3106 of the steam generating device.

  In the water level detection chamber cover 3106, among the corners of the top surface of the bottom 3160, the corners on the first wall 161 side are rounded.

  In the water level detection chamber cover 3106, among the corners of the top surface of the bottom 3160, the corners on the first wall 161 side are rounded. That is, the inner surface of the corner formed by the first wall portion 3161 and the third and fourth wall portions 3163 and 3164 has an arc shape in plan view.

  Further, the upper surface of the bottom 3160 includes a first inclined surface 3181 as an example of an inclined surface, and second and third inclined surfaces 3182 and 3183 provided so as to sandwich the first inclined surface 3181. The first inclined surface 3181, the second inclined surface 3182 and the third inclined surface 3183 are similar to the first inclined surface 181, the second inclined surface 182 and the third inclined surface 183 of the first embodiment with respect to the horizontal plane. It is inclined.

  In the heating cooker configured as described above, the corner on the first wall 3161 side of the top surface of the bottom 3160 of the water level detection chamber cover 3106 is rounded, so water on the corner is on the second wall 162 side It becomes easy to flow.

  In the third embodiment, the above-mentioned radius is formed by a part of each of the first wall portion 3161, the third wall portion 3163 and the fourth wall portion 3164, but the first wall portion 3161, the third wall portion 3163 And the fourth wall 3164 may be formed separately.

  In the third embodiment, the corner on the second wall 162 side of the top surface of the bottom 3160 is not rounded, but may be rounded in the same manner as the corner on the first wall 161 side.

  In the steam generating apparatus of the present invention, the shape of the water level detection chamber cover is not limited to that of the first to third embodiments, and may be appropriately set according to the configuration of the steam generation container or the like.

  Although the said 1st-3rd embodiment demonstrated the heating cooker which used the steam generation apparatus, you may use the steam generation apparatus of this invention for the other apparatus using a vapor | steam.

  Although the specific embodiment of this invention was described, this invention is not limited to the said 1st-3rd embodiment, It can change variously within the scope of this invention, and can be implemented.

The steam generator 100 according to one aspect of the present invention is
A steam generating container 101 for storing water inside;
A heater 103 for heating water in the steam generation container 101;
A water level sensor 105 for detecting the water level in the steam generation container 101;
The first wall portion 161, 2161, 3161 disposed on one side of the water level sensor 105 and provided with the first through holes 172, 2172 and the other side of the water level sensor 105, the second A cover 106, 2106, 3106 having a second wall portion 162 provided with a through hole 173, and a bottom portion 160, 2160, 3160 disposed below the water level sensor 105;
The upper surfaces of the bottoms 160, 2160, 3160 of the covers 106, 2106, 3106 are inclined with respect to the horizontal direction so that the second wall 162 side is lower than the first wall 161, 2161, 3161 side. And inclined surfaces 181, 2181, and 3181.

  According to the above configuration, when the water in the steam generating container 101 is boiled by the heater 103, steam is generated in the steam generating container 101. At this time, since bottom portions 160 2160 3160 of the covers 106 2106 3106 are located below the water level sensor 105, boiling bubbles generated in the vicinity of the water level sensor 105 can be reduced. Therefore, the accuracy of water level detection by the water level sensor 105 can be enhanced.

  Further, the upper surfaces of the bottom portions 160 2160 3160 of the covers 106 2106 3106 include inclined surfaces 181 2 181 1 3181. The inclined surfaces 181, 2181, and 3181 are inclined with respect to the horizontal surface such that the second wall portion 162 side is lower than the first wall portions 161, 2161, and 3161 side. As a result, the water on the bottom portions 160, 2160, 3160 of the covers 106, 2106, 3106 can be flowed from the first wall portions 161, 2161, 3161 side to the second wall portion 162 side, so the covers 106, 2106, Drainage on the bottom 160 2160 3160 of the 3106 is improved. Therefore, the water remaining on the bottoms 160 2160 3160 of the covers 106 2106 3106 can be reduced.

  Further, since the water remaining on the bottoms 160 2160 3160 of the covers 106 2106 3106 can be reduced, the scale generated on the bottoms 160 2160 3160 of the covers 106 2106 3106 is also reduced. Can.

In the steam generating apparatus 100 of this one embodiment,
The bottoms 160, 2160, 3160 of the covers 106, 2106, 3106 are provided with drains 174 communicating with the second through holes 173, respectively.

  According to the above embodiment, since the drainage port 174 is provided in the bottom portions 160 2160 3160 of the covers 106 2106 3106, the drainage property on the bottom portions 160 2160 3160 of the covers 106 2106 3106 It can be further improved.

  Further, since the drainage port 174 communicates with the second through hole 173, it is possible to suppress that the water film can be formed into the drainage port 174 by surface tension.

In the steam generating apparatus 100 of this one embodiment,
At the peripheral portion of the drainage port 174, water guide portions 167A and 167B which protrude downward from the bottom portions 160, 2160 and 3160 are provided.

  According to the above embodiment, since the water guides 167A and 167B are provided at the peripheral edge of the drain 174, the water in the drain 174 can be positively flowed downward by the water guides 167A and 167B. . As a result, it is possible to enhance the effect of suppressing that the water film can be formed in the drainage port 174 by surface tension.

In the steam generating apparatus 100 of this one embodiment,
The water level sensor 105 is disposed so as not to face the drainage port 174 in the vertical direction.

  According to the above embodiment, by disposing the water level sensor 105 so as not to face the drainage port 174 in the vertical direction, even if the boiling foam rises through the drainage port 174, the boiling foam is the water level The probability of reaching the vicinity of the sensor 105 is low.

In the steam generating apparatus 100 of this one embodiment,
The heater 103 has a terminal portion 103a,
The water level sensor 105 is located on the terminal portion 103 a side of the heater 103.

  According to the above-described embodiment, the water temperature on the terminal portion 103a side of the heater 103 is relatively low in the vapor generation container 101, so the boiling bubbles generated in the region on the terminal portion 103a side are relatively small. Therefore, by disposing the water level sensor 105 on the terminal portion 103 a side of the heater 103, boiling bubbles generated in the vicinity of the water level sensor 105 can be reduced.

In the steam generating apparatus 100 of this one embodiment,
The heater 103 has a terminal portion 103a,
The second wall portion 162 is located on the terminal portion 103 a side of the heater 103.

  According to the above-described embodiment, by arranging the second wall portion 162 on the terminal portion 103a side of the heater 103, the bottom of the cover 106, 2106, 3106 or the bottom portion 160, 2160 of a region where water convection is relatively gentle. The water on the 3160 can be flushed. Accordingly, the water on the bottoms 160 2160 3160 of the covers 106 2106 3106 can easily flow out of the covers 106 2106 3106.

In the steam generating apparatus 100 of this one embodiment,
The inner surface of the first wall portion 2161 includes an inclined surface 2184 which is inclined with respect to the vertical surface so that the lower end is positioned closer to the second wall portion 162 than the upper end.

  According to the above embodiment, the inclined surface 2184 is inclined with respect to the vertical surface so that the lower end is positioned closer to the second wall portion 162 than the upper end, and thus the inner surface of the first wall portion 2161 is on the bottom 2160. The water that has fallen down can be flushed to the second wall portion 162 side. Accordingly, the water can easily reach the second through hole 173 of the second wall portion 162.

In the steam generating apparatus 100 of this one embodiment,
Among the corners of the top surface of the bottom 3160 of the cover 3106, at least the corner on the first wall portion 3161 side is rounded.

  According to the above embodiment, the corner on the side of the first wall portion 3161 is rounded on the upper surface of the bottom 3160 of the cover 3106, so water on the corner can easily flow to the side of the second wall portion 162. . That is, water hardly remains on the corners.

The heating cooker according to one aspect of the present invention is
Any one of the steam generators 100 described above;
And a heating chamber 2 to which the steam from the steam generator 100 is supplied.

  According to the above configuration, by providing the steam generation device 100 of any one of the above-described steam generation devices 100, the scale generated in the steam generation device 100 can be reduced, so that sanitary steam is supplied to the heating chamber 2 can do.

DESCRIPTION OF SYMBOLS 1 main body casing 2 heating chamber 2a opening part 100 steam generation apparatus 101 steam generation container 101a opening part 101b bottom part 102 lid part 102a main body part 102b flange part 102c insertion part 102d convex part 103 heater for steam generation 103a connection terminal 103b heating part 105 water level Sensor 105a, 105b Electrode rod 106, 2106, 3106 Water level detection chamber cover 161, 2161, 3161 First wall 162 Second wall 163, 3163 Third wall 164, 3164 Fourth wall 167A, 167B Water guide 171 first upper through hole 172, 2172 first lower through hole 173 second through hole 174 drainage port 181, 2181, 3181 first inclined surface 182, 3182 second inclined surface 183, 3183 third inclined surface 2184 inclined surface P1 steam Occurrence space P2 water level The outlet chamber

Claims (7)

A steam generating container for storing water inside;
A heater for heating water in the steam generation container;
A water level sensor for detecting the water level in the steam generation container;
A first wall portion disposed on one side of the water level sensor and provided with a first through hole, and a second wall portion disposed on the other side of the water level sensor and provided with a second through hole And a cover having a bottom disposed below the water level sensor,
The upper surface of the bottom of the cover includes an inclined surface which is inclined with respect to the horizontal direction such that the second wall side is lower than the first wall side. In the steam generator according to claim 1,
The bottom of the cover is provided with a drain port communicating with the second through hole. In the steam generator according to claim 2,
A steam generating apparatus characterized in that a water guide portion which protrudes downward from the bottom portion is provided at a peripheral portion of the drainage port. In the steam generator according to claim 2 or 3,
The said water level sensor is arrange | positioned so that it may not oppose the said drainage port in the perpendicular direction, The steam generator characterized by the above-mentioned. The steam generator according to any one of claims 1 to 4,
The heater has a terminal portion,
The said 2nd wall part is located in the said terminal part side of the said heater, The steam generator characterized by the above-mentioned. The steam generator according to any one of claims 1 to 5,
An inner surface of the first wall includes an inclined surface which is inclined with respect to a vertical surface such that a lower end is positioned closer to the second wall than an upper end. The steam generator according to any one of claims 1 to 6,
And a heating chamber to which the steam from the steam generator is supplied.

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