Patent Application
20180327281
The present invention relates to a water treatment device and a heating cooker provided with the water treatment device.
In this type of a water treatment device and a heating cooker provided with the water treatment device, a suction tube in which a water treatment material is sealed is conventionally provided in a liquid container in a state of being immersed in a liquid (for example, see PTL 1).
PTL 1: Unexamined Japanese Patent Publication No. H10-110903
However, the suction tube in which the water treatment material is sealed is always immersed in the liquid, and thus upon replacement of the suction tube, water adhered to the suction tube drips, so that a surrounding area is wet. Consequently, it is necessary to perform a troublesome operation of wiping off the water adhered to the suction tube before the replacement of the suction tube. In addition, it is unsanitary because mold, bacteria, and the like easily propagate on an outer side of the suction tube.
An object of the present invention is to provide a water treatment device in which upon replacement of a suction tube, the suction tube can be easily replaced without any water dripping and can be kept sanitary, and a heating cooker provided with the water treatment device.
A water treatment device and a heating cooker provided with the water treatment device according to the present invention include a water supply tank that stores water, a water treatment container communicating with the water supply tank, in which a water treatment material for treating water passing through the water treatment material is sealed, and a water supply device that communicates with the water treatment container and sucks up water in the water supply tank via the water treatment container. The water treatment container is detachably connected to outside of the water supply tank.
The water treatment container is not always immersed in water in the water supply tank, and thus upon replacement of the water treatment container, the water treatment container can be easily replaced without water dripping and wetting the surrounding area. In addition, mold, bacteria, and the like hardly propagate on an outer side of the water treatment container and the water treatment container can be kept sanitary.
Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the exemplary embodiments.
In
Water supply tank lid 29 with a water filler (not shown) is provided on an upper part of water supply tank 2. Water supply tank 2 and water supply tank lid 29 are formed of a transparent resin so that an amount of water stored can be easily checked. Water supply tank 2 has recess 28 for receiving a finger so as to be easily taken out of tank case 3.
While discharge port 4 is provided on an upper portion of tank case 3 in the present exemplary embodiment, discharge port 4 may be provided on a lower portion or a side surface of tank case 3. While water treatment device 1 has switch 5 that switches ON and OFF the operation of water treatment device 1, water treatment device 1 may include an operation unit that can specifically set a flow rate or may be connected to other devices to be operated by the other devices.
In
In
Water treatment container 7 is formed in a substantially rectangular parallelepiped shape that is horizontally symmetric, and can be attached to water treatment container accommodating part 8 even if water treatment container 7 is upside down. Water treatment container 7 does not need to be formed in a cylindrical shape or be horizontally symmetric.
In
Water treatment material 13 that is sandwiched between mesh members 14a, 14b obtained by integrally molding a resin mesh with a resin (see
Water treatment material 13 is made of a particulate ion exchange resin that converts cations such as calcium ions in the water into hydrogen ions and anions such as silica ions into hydroxide ions to purify the water. The water treated by water treatment material 13 is used for drinking, or is supplied to a steam generating device to prevent scale components such as calcium and silica from being deposited and adhered to the steam generating device.
While the ion exchange resin that purifies water is used as water treatment material 13 in the present exemplary embodiment, any material that removes predetermined components in the water according to applications, including an ion exchange resin that removes only cations in the water and substitutes the cations for sodium ions to soften the water, may be used.
An opening of the resin mesh constituting mesh members 14a, 14b has a diameter of approximately 0.15 mm. This diameter is set to be smaller than a particle diameter of water treatment material 13 of approximately 0.3 mm, for the purpose of preventing particles of water treatment material 13 from passing through the openings.
Diffusion spaces 15a, 15b are respectively defined by mesh members 14a, 14b on both sides of water treatment material 13 in water treatment container 7, for the purpose of enabling entering or exiting water to pass through overall water treatment material 13 and extending a lifetime of water treatment material 13.
In
Valve spring 19a, valve shaft 20a that is always pressed rearward (a right side in
In
An end of water supply pipe 23 with an elbow cross-section in a longitudinal direction is attached to outside of water treatment container connection-part 18 by a press-fit, for the purpose of sucking up the water at a bottom of water storage chamber 6.
In
In
Valve spring 19b, valve shaft 20b that is always pressed rearward by valve spring 19b, and valve 22b formed of a silicone rubber are included in water supply pump connection-part 12. Valve 22b has valve shaft 20b passing through valve shaft hole 21b, and is formed on the front of valve shaft 20b.
In
In
A press-contact area of O-ring 17a and the inner wall of water treatment container connection-part 18 is increased to increase bonding force of water treatment container inlet port 16 and the inner wall of water treatment container connection-part 18 of water supply tank 2 more than bonding force of water supply pump inlet port 24 and the inner wall of water supply pump connection-part 12 of water treatment container 7. With this configuration, when water supply tank 2 is taken out, it is possible to prevent water treatment container 7 from being removed from water supply tank 2 and remaining on a side of water supply pump 9.
A press-contact area of O-ring 17b and the inner wall of water supply pump connection-part 12 may be reduced to reduce the bonding force of water supply pump inlet port 24 and the inner wall of water supply pump connection-part 12 of water treatment container 7. Alternatively, the bonding force may be increased or reduced by other methods, such as by using friction between resins or by using lubricants.
The operation and effect of the water treatment device having the above-mentioned configuration are hereinafter described.
A user of water treatment device 1 first pulls out water supply tank 2 from tank case 3, pours water from a water filler (not shown) into water storage chamber 6 in water supply tank 2, and inserts water supply tank 2 fully into tank case 3.
Next, when switch 5 is turned ON, water supply pump 9 serving as a water supply device sucks up water in water storage chamber 6 through water supply pipe 23, valve shaft hole 21a, water treatment container inlet port 16, diffusion space 15a, mesh member 14a, water treatment material 13, mesh member 14b, diffusion space 15b, valve shaft hole 21b, and water supply pump inlet port 24. While the water passes through water treatment material 13, cations such as calcium ions in the water are converted into hydrogen ions and anions such as silica ions are converted into hydroxide ions. The sucked water then passes through water supply passage 10 to be externally ejected from discharge port 4.
When water treatment container 7 is replaced, water supply tank 2 is first taken out of tank case 3. At this time, water treatment container 7 that is connected to the outside of water supply tank 2 is also taken out with water supply tank 2. Next, water treatment container 7 is slid to be taken out of water supply tank 2. In this state, water treatment container 7 is not immersed in water storage chamber 6 in water supply tank 2. In addition, valves 22a, 22b are closed and thus when water treatment container 7 is taken out, water hardly drips from water treatment container 7 and water supply tank 2. As a result, it is possible to easily replace water treatment container 7.
As described above, according to the present exemplary embodiment, water supply tank 2 that stores water, water treatment container 7 communicating with water supply tank 2, in which water treatment material 13 for treating water passing through water treatment material 13 is sealed, and water supply pump 9, serving as a water supply device, that communicates with water treatment container 7 and sucks up the water in water supply tank 2 via water treatment container 7 are provided. Water treatment container 7 is connected to the outside of water supply tank 2 to be easily detachable from water supply tank 2, and thus water treatment container 7 is not always immersed in the water in water supply tank 2. As a result, water treatment container 7 can be easily replaced without water dripping and wetting the surrounding area upon replacement of water treatment container 7. Additionally, mold, bacteria, and the like hardly propagate on an outer side of water treatment container 7, and thus water treatment container 7 can be kept sanitary.
It is configured to include tank case 3 that includes water supply pump 9 serving as a water supply device and accommodates water supply tank 2 and water treatment container 7 to be easily detachable. In addition, it is configured such that water supply tank 2 can be taken out of tank case 3 while being connected to water treatment container 7. With this configuration, when water supply tank 2 is taken out, it is possible to prevent only water treatment container 7 from remaining in tank case 3 and being difficult to be replaced.
In addition, bonding force of a connection part connecting water treatment container 7 and water supply tank 2 is set to be greater than bonding force of a connection part connecting water treatment container 7 and water supply pump 9. With this configuration, when water supply tank 2 is taken out, it is possible to take water supply tank 2 out of tank case 3 while water treatment container 7 is securely connected to water supply tank 2. Only by adjusting bonding force of a joining part, it is possible to easily prevent water treatment container 7 from remaining in tank case 3 and from being difficult to be replaced.
Moreover, water supply tank 2 includes valve 22a that switches a communication state of water supply tank 2 with water treatment container 7 at a connection part connecting the water supply tank 2 to water treatment container 7. With this configuration, when water treatment container 7 is removed from water supply tank 2 to be replaced, it is possible to prevent the water in water supply tank 2 from dripping from a joining part to water treatment container 7 and wetting the surrounding area. As a result, it is possible to reduce troublesomeness of replacing water treatment container 7.
Moreover, water treatment container 7 includes valve 22b that switches a communication state of water treatment container 7 with water supply pump 9 at a connection part to water supply pump 9 serving as a water supply device. With this configuration, when water supply tank 2 to which water treatment container 7 is attached is taken out of tank case 3, it is possible to prevent the water in water treatment container 7 from dripping from a joining part to water supply pump 9 serving as a water supply device and wetting the surrounding area. As a result, it is possible to reduce troublesomeness of taking out water supply tank 2, to which water treatment container 7 is attached, from tank case 3.
If a user forgets to connect water treatment container 7 to water supply tank 2, it is impossible to drive water supply pump 9 to suck up water from water supply tank 2. It is thus possible to prevent a case where the user forgets to attach water treatment container 7 to water supply tank 2 and thus water cannot be treated.
Next, a second exemplary embodiment of the present invention will be described. Differences from configurations and operations of the first exemplary embodiment are mainly described below. Same reference marks are given to same elements as those of the first exemplary embodiment, and detailed descriptions of configurations and operations of the same elements are omitted.
In
Stopper 25 is screwing part 27 that is provided in stopper 25 and water supply tank 2 to prevent water treatment container 7 from being easily removed from water supply tank 2. Stopper 25 is fixed to water supply tank 2 by a screw. Upon replacement of water treatment container 7, a user loosens the screw, takes out water treatment container 7, and replaces water treatment container 7.
While stopper 25 is fixed to water supply tank 2 by a screw in the present exemplary embodiment, stopper 25 may be fixed to water supply tank 2 by hooking a claw formed at stopper 25 on water supply tank 2 or by a press-fit.
If stopper 25 is pressed by an elastic body such as a spring to project from water supply tank 2 and to be hooked on water treatment container 7 for the purpose of preventing removal of water treatment container 7, the spring is deformed when water treatment container 7 is attached to or taken out of water supply tank 2 and thus stopper 25 does not need to be especially removed. A user can thus easily take out water treatment container 7. Stopper 25 itself may be constituted by an elastic body such as a plate spring.
A part of water supply tank 2 is formed on the upper surface of water treatment container 7. Water supply tank 2 is shaped in a manner that upper surfaces of four side walls of water supply tank 2 form a substantially hollow rectangular shape, packing (not shown) serving as a seal member for a lid member also has a substantially rectangular shape that is easily molded, and a sealing property is easily achieved using the packing. It is thus possible to easily configure a mechanism for preventing water leakage from water supply tank 2.
In addition, water treatment container guides 26 do not cover the overall lower surface of water treatment container 7 and a gap is present between water treatment container guides 26. Consequently, when water treatment container 7 is replaced, a user removes stopper 25, holds water treatment container 7 with fingers through the gap, slides water treatment container 7, thus easily taking out water treatment container 7.
As described above, stopper 25 that prevents water treatment container 7 from being removed from water supply tank 2 is provided in the present exemplary embodiment. Consequently, if water supply tank 2 is taken out and then is shook, dropped, or improperly handled, water treatment container 7 is not removed from water supply tank 2 and thus portability can be improved.
Next, a third exemplary embodiment of the present invention will be described. Differences from configurations and operations of the first exemplary embodiment are mainly described below. Same reference marks are given to same elements as those of the first exemplary embodiment, and detailed descriptions of configurations and operations of the same elements are omitted.
In
Bottom plate 54 supporting heating chamber 52 is provided under heating cooker 51. Tank case 3 supporting bottom plate 54 is provided under bottom plate 54. Tank case 3 accommodates water supply tank 2 and drain water tank 56 to be easily detachable on a substantially whole side of tank case 3 where the opening of heating chamber 52 is formed.
Recesses 28a, 28b are formed in a front part of tank case 3 for a user to easily put or take water supply tank 2 and drain water tank 56 in or out of tank case 3 with a hand. Water supply tank 2 is formed of a transparent resin so that an amount of water stored can be easily checked. A plurality of cooling air inlet ports 55 for taking cooling air in heating cooker 51 are formed above water supply tank 2 and drain water tank 56 and on a side of bottom plate 54 where the opening of heating chamber 52 is formed.
In the present exemplary embodiment, a following description is made assuming that a side of the opening of heating chamber 52 is referred to as front, a right side when a user faces rear while standing at the front is referred to as right, and a left side when the user faces the main body while standing at the front is referred to as left.
Door 53 is formed to be vertically openable. Operation display unit 57 for a user to set a cooking menu and a cooking time is formed on a front surface of door 53. A safety switch (not shown) for stopping operations of heat sources in heating cooker 51 when door 53 is opened is provided in the main body of heating cooker 51.
In
The wall surfaces of heating chamber 52 are grounded by an earth cord (not shown). Rail 60 is integrally molded with each of left and right side walls of heating chamber 52 to easily detachably hold a tray (not shown). Consequently, rails 60 are also grounded.
While the wall surface of heating chamber 52 is coated with fluorine so that dirt can be easily wiped off in the present exemplary embodiment, the wall surface may be coated with enamel or other heat-resistant coating may be performed on the wall surface. Alternatively, stainless may be used as a material for the wall surface of heating chamber 52.
A plurality of heating chamber exhaust holes 62 for externally discharging air in heating chamber 52 are formed in an upper right part of partition wall 61, which is an innermost wall of heating chamber 52. Infrared sensor 65 and in-chamber thermistor 63 are provided on an upper part of the right wall of heating chamber 52. Infrared sensor 65 detects a temperature of a food in heating chamber 52 or a temperature of a food container in heating chamber 52 through detection hole 64 formed in the right wall of heating chamber 52. In-chamber thermistor 63 detects an in-chamber atmosphere temperature.
Steam generating device 66 that generates steam is provided under and outside heating chamber 52. Steam introduction passage 67 is connected to an upper part of steam generating device 66 to supply steam from a left side surface of heating chamber 52 into heating chamber 52. Steam ejection port 68, which is at a distal end of steam introduction passage 67, is fixed to the side wall of heating chamber 52 to eject steam horizontally into heating chamber 52.
Tank case 3, and water supply tank 2 and drain water tank 56 accommodated in tank case 3 are provided below steam generating device 66. Steam generating device 66 is connected via water supply pump 9 and electric conductivity measurement device 69 to water supply tank 2 by water supply passage 10.
One end of drain passage 70 that drains water from steam generating device 66 is connected to steam generating device 66. The other end of drain passage 70 passes through drain valve 71 to extend above drain water tank 56. Consequently, when drain valve 71 is opened, water in steam generating device 66 is drained into drain water tank 56. Drain valve 71 is normally closed and thus the water in steam generating device 66 is not drained. Steam introduction passage 67 and drain passage 70 are formed of a silicone tube.
While water supply tank 2 is disposed on the right and drain water tank 56 is disposed on the left in the present exemplary embodiment, water supply tank 2 may be disposed on the left and drain water tank 56 may be disposed on the right. Alternatively, water supply tank 2 and drain water tank 56 may be disposed in a front-rear direction.
Tank case 3 includes center part partition 72 formed between water supply tank 2 and drain water tank 56, water supply tank guide 73 that is formed on both sides of an upper part of water supply tank 2 and functions as a guide when water supply tank 2 is pulled out, and drain water tank guide 74 that is formed on both sides of an upper part of drain water tank 56 and functions as a guide when drain water tank 56 is pulled out. Bottom plate 54 can be supported by and fixed to tank case 3 from below using a left wall, a right wall, and a rear wall of tank case 3.
Food 100 is disposed on a bottom part of heating chamber 52.
In
A plurality of intake vent holes 77 are formed near a center of partition wall 61 for the purpose of blowing the air in heating chamber 52 toward a side of circulation fan 75. A plurality of blowing vent holes 78 are formed in a peripheral edge of partition wall 61, so that air in the space partitioned by partition wall 61 is heated by convection heater 76 and heated air is blown toward a side of heating chamber 52 through the plurality of blowing vent holes 78.
Magnetron 80, which is a microwave generation device, is provided outside heating chamber 52 and on the rear of heating chamber 52 so as to face vertically upward, and is connected to waveguide 81 that transmits microwaves to heating chamber 52. Waveguide 81 has an internal passage formed by bending and welding two aluminum-plated steel plates.
Rotating antenna 82 is provided near the center of heating chamber 52 in a horizontal direction. Rotating antenna 82 is formed of an aluminum-plated steel plate and is connected to motor 83, thus stirring microwaves and irradiating microwaves on heating chamber 52.
While magnetron 80, waveguide 81, rotating antenna 82, and motor 83 are provided in an upper portion of heating chamber 52, these components may be provided on a side of a lower surface or a side surface. Any direction may be set as installation direction.
Microwaves may be supplied to heating chamber 52 only from an opening at an exit of waveguide 81 without providing rotating antenna 82. Additionally, to improve a heating distribution, a turntable that rotates with a food being disposed thereon may be provided on the bottom part of heating chamber 52.
Cooling fan 79 is provided below magnetron 80. Cooling fan 79 takes in cooling air from cooling air inlet ports 55 and cools inside of heating cooker 51.
Controller 84 is provided above cooling fan 79. When a user selects a cooking menu, controller 84 controls magnetron 80, motor 83, circulation fan 75, cooling fan 79, heaters, thermistors, infrared sensor 65, water supply pump 9, operation display unit 57, electric conductivity measurement device 69, an in-chamber lamp (not shown), and the like.
In electric conductivity measurement device 69 at the bottom of heating cooker 51, electric conductivity measurement chamber 87 is constituted by box-shaped rib 85 projecting upward from a bottom part of tank case 3 and electric conductivity measurement chamber cover 86. Electric conductivity measurement chamber cover 86 and rib 85 are sealed by packing (not shown) so that water does not leak out. Two electrodes 88a, 88b made of a stainless steel plate are integrally molded with electric conductivity measurement chamber cover 86. Electrodes 88a, 88b are electrically connected to controller 84 by lead wires.
Water is filled with electric conductivity measurement chamber 87, and then electric conductivity measurement device 69 applies an AC voltage between electrodes 88a, 88b to measure electrical resistance and calculate electric conductivity. When water is almost pure water and no ions are present in the water, the electric conductivity is low. On the other hand, when many ions are present in the water, the electric conductivity is high. The AC voltage is applied to electrodes 88a, 88b, because if a DC voltage is applied, air bubbles are generated on surfaces of electrodes 88a, 88b by electrolysis and thus the electrical resistance cannot be measured correctly.
In
The operation and effect of the heating cooker having the above-mentioned configuration are hereinafter described.
An operation in steam heating is described first.
A user of heating cooker 51 first pulls out water supply tank 2 from tank case 3, pours water in water storage chamber 6 of water supply tank 2 from a water filler (not shown), and inserts water supply tank 2 fully into tank case 3. The user also inserts drain water tank 56 fully into tank case 3.
Next, the user opens door 53, disposes food 100 in heating chamber 52, closes door 53, selects a steam heating operation menu through operation display unit 57, and starts heating.
When heating starts, steam generating device 66 generates heat and thus a temperature of steam generating device 66 increases sufficiently. Water supply pump 9 then sucks up the water in water storage chamber 6 through water supply pipe 23, valve shaft hole 21a, water treatment container inlet port 16, diffusion space 15a, mesh member 14a, water treatment material 13, mesh member 14b, diffusion space 15b, valve shaft hole 21b, and water supply pump inlet port 24.
While the water passes through water treatment material 13, cations such as calcium ions in the water are converted into hydrogen ions and anions such as silica ions are converted into hydroxide ions. Scale components of the cations and the anions are adsorbed by water treatment material 13, so that the scale components in the water can be removed.
The sucked water is supplied via electric conductivity measurement device 69 and water supply passage 10 to steam generating device 66, which instantaneously generates steam. Since the scale components of the supplied water are removed, it is possible to prevent the scale components from being deposited and adhered to steam generating device 66. Steam may be gradually generated by storing water in steam generating device 66 and heating the water.
Generated steam passes through steam introduction passage 67 to be ejected from steam ejection port 68. Steam ejected from steam ejection port 68 reaches proximity of food 100, condenses into droplets around food 100, applies evaporation latent heat to food 100, thus heating food 100. In particular, when food 100 has many spaces (for example, noodles) or is porous, steam enters food 100 and thus food 100 can be efficiently heated from inside.
When it is detected that the temperature of steam generating device 66 is increased, cooling fan 79 is operated to take in cooling air from cooling air inlet ports 55 and to cool controller 84 and magnetron 80 while preventing an increase in a temperature of steam generating device 66 and near steam generating device 66.
Drain valve 71 is operated almost simultaneously with when heating ends to open drain passage 70 and drain the water in steam generating device 66. After a while, drain valve 71 is operated again to close drain passage 70.
It is needless to mention that when heating is performed continuously, drain passage 70 may be kept closed for a while and thus hot water is stored in steam generating device 66 to quickly generate steam. Alternatively, only when an instruction for water drainage is made by the user, drain passage 70 may be opened. Even if the user forgets to drain water stored in drain water tank 56, the water is automatically drained and thus it is possible to prevent the water from overflowing drain water tank 56.
After heating ends, the user of heating cooker 51 opens door 53 and takes food 100 out of heating cooker 51.
While performance of water treatment material 13 is kept, water treatment material 13 can remove scale components of water as described above, and thus the electric conductivity is low. However, as water treatment continues to be performed, a function of water treatment material 13 to remove the scale components of the water is degraded, and thus the electric conductivity is gradually increased. For example, when electric conductivity measurement device 69 determines that the electric conductivity is equal to or larger than 10 mS/m, it is informed to operation display unit 57 that water treatment material 13 has reached a lifetime and thus water treatment container 7 needs to be replaced. While a value for determining the lifetime is 10 mS/m in the present exemplary embodiment, the value is not limited to 10 mS/m depending on water to be supplied. Moreover, replacement may be informed to a user by turning on a lamp or by sound.
When water treatment container 7 is replaced, water supply tank 2 is first taken out of tank case 3. At this time, water treatment container 7 that is connected to the outside of water supply tank 2 is also taken out with water supply tank 2. Water treatment container 7 is not immersed in water storage chamber 6 in water supply tank 2 and further valves 22a, 22b are closed. Consequently, when water treatment container 7 and water supply tank 2 are taken out, water hardly drips from water treatment container 7 and water supply tank 2 and thus water treatment container 7 can be easily replaced.
Next, an operation in microwave heating is described.
A user of heating cooker 51 opens door 53, disposes food 100 in heating chamber 52, closes door 53, selects a microwave heating operation menu through operation display unit 57, and starts heating. Microwaves are then output from magnetron 80. The microwaves propagate in waveguide 81 to be supplied to rotating antenna 82 rotated by motor 83. The microwaves are stirred and irradiated in heating chamber 52 through rotating antenna 82.
Most microwaves are directly absorbed by food 100 to generate heat. Rotation control of rotating antenna 82 enables a distribution of microwaves in heating chamber 52 to be changed. It is possible to select appropriate distribution performance depending on a type, a shape, a position, and a number of foods 100.
While magnetron 80 is operated, cooling fan 79 is operated to take in cooling air from cooling air inlet ports 55 and to cool controller 84 and magnetron 80.
Next, an operation in oven heating is described.
A user of heating cooker 51 opens door 53, disposes food 100 on a tray (not shown) in heating chamber 52, closes door 53, selects an oven heating operation menu through operation display unit 57, and starts heating. Convection heater 76 generates heat and circulation fan 75 starts to rotate.
As circulation fan 75 is rotated, air in heating chamber 52 is taken in from intake vent holes 77 to be heated by convection heater 76. Heated air is then returned to heating chamber 52 again through blowing vent holes 36. In this way, the air in heating chamber 52 is circulated to increase the temperature of heating chamber 52 for the purpose of heating food 100.
During oven heating, cooling fan 79 is operated to take in cooling air from cooling air inlet ports 55 and to cool controller 84 and magnetron 80 while preventing heat from being transferred from heating chamber 52 to water supply tank 2 and drain water tank 56. After the oven operation ends, cooling fan 79 is operated for a while to prevent heat transfer from heating chamber 52.
While the present exemplary embodiment shows heating only by steam, heating only by microwaves, and heating only by an oven, it is possible to perform grill heating by heating chamber heater 59 and composite heating by microwaves and steam. In addition, it is possible to perform heating only by radiant heat or hot air generated by using heating chamber heater 59 and convection heater 76, or to perform composite heating by radiant heat and hot air.
As described above, heating cooker 51 provided with water treatment device 1 is provided in the present exemplary embodiment. As water treatment container 7 is not always immersed in water in water supply tank 2, it is possible to easily replace water treatment container 7 without any water dripping upon replacement of water treatment container 7. In addition, it is possible to provide heating cooker 51 provided with water treatment device 1 in which mold, bacteria, and the like hardly propagate on an outer side of water treatment container 7, and thus water treatment container 7 can be kept sanitary.
In electric conductivity measurement device 69, electric conductivity measurement chamber 87 is formed by box-shaped rib 85 projecting upward from the bottom part of tank case 3 and electric conductivity measurement chamber cover 86. As electric conductivity measurement chamber 87 is constituted only by tank case 3 and electric conductivity measurement chamber cover 86, the number of components can be reduced. In addition, it is possible to achieve inexpensive electric conductivity measurement chamber 87 without any water leakage.
While heating cooker 51 provided with water treatment device 1 is shown in the present exemplary embodiment, water treatment device 1 may be provided in other devices.
In addition, when electric conductivity measurement device 69 is added to the first exemplary embodiment or the second exemplary embodiment, a lifetime of water treatment device 1 can be detected.
As described above, the present invention includes a water supply tank that stores water, a water treatment container communicating with the water supply tank, in which a water treatment material for treating water passing through the water treatment material is sealed, and a water supply device that communicates with the water treatment container and sucks up water in the water supply tank via the water treatment container. In addition, the water treatment container is detachably connected to outside of the water supply tank.
According to this configuration, the water treatment container is not always immersed in water in the water supply tank, and thus upon replacement of the water treatment container, the water treatment container can be easily replaced without water dripping and wetting the surrounding area. In addition, mold, bacteria, and the like hardly propagate on an outer side of the water treatment container and the water treatment container can be kept sanitary.
The present invention may be configured to include a tank case that includes the water supply device and accommodates the water supply tank and the water treatment container to be detachable from the tank case. Additionally, the present invention may be configured in a manner that the water supply tank and the water treatment container can be taken out of the tank case while being connected to each other.
With this configuration, when the water supply tank is taken out, it is possible to prevent only the water treatment container from remaining in the tank case and being difficult to be replaced.
Moreover, according to the present invention, bonding force of a connection part connecting the water treatment container and the water supply tank may be greater than bonding force of a connection part connecting the water treatment container and the water supply device.
With this configuration, it is possible to take the water supply tank out of the tank case while being securely connected to the water treatment container. Only by adjusting bonding force of the connection part, it is easily possible to prevent the water treatment container from remaining in the tank case and from being difficult to be replaced.
Additionally, the present invention may include a stopper that prevents the water treatment container from being removed from the water supply tank.
According to this configuration, if the water supply tank is taken out and then is shook, dropped, or improperly handled, the water treatment container is not removed from the water supply tank and thus portability can be improved.
Moreover, the present invention may include a valve that switches a communication state of the water supply tank with the water treatment container at a connection part connecting the water supply tank to the water treatment container.
With this configuration, when the water treatment container is removed from the water supply tank to be replaced, it is possible to prevent water in the water supply tank from dripping from a joining part to the water treatment container and wetting the surrounding area. It is thus possible to reduce troublesomeness of replacing the water treatment container.
Additionally, the present invention may include a valve that switches a communication state of the water treatment container with the water supply device at a connection part connecting the water treatment container to the water supply device.
With this configuration, when the water supply tank to which the water treatment container is attached is taken out of the tank case, it is possible to prevent water in the water treatment container from dripping from a joining part to the water supply device and wetting the surrounding area. It is thus possible to reduce troublesomeness of taking out the water supply tank, to which the water treatment container is attached, from the tank case.
Additionally, the present invention may be a heating cooker provided with the water treatment device described above.
According to this configuration, the water treatment container is not always immersed in the water in the water supply tank, and thus upon replacement of the water treatment container, it is possible to easily replace the water treatment container without any water dripping. In addition, it is possible to provide the heating cooker provided with the water treatment device in which mold, bacteria, and the like hardly propagate on the outer side of the water treatment container, and thus the water treatment container can be kept sanitary.
As described above, a water treatment device and a heating cooker provided with the water treatment device according to the present invention are applicable to a water purifier, and a microwave oven, an oven microwave oven, a steam convection oven, a steamer, and a dish washer and dryer, which are provided with a steam generating device, and the like.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2015-244775 | Dec 2015 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2016/004617 | 10/19/2016 | WO | 00 |
