JP2021087592A - Steamer - Google Patents

Abstract

To provide a steamer capable of smoothly blowing steam from a blowing portion even in a cordless state.SOLUTION: The steamer of the present invention includes: a tank assembly body 17 for storing a liquid inside; a base 7 disposed beneath the tank assembly body 17, and provided with a heater 6; a vaporization chamber 11 heated with the heater 6 for vaporizing the liquid from the tank assembly body 17; a steam hole 12 for blowing steam vaporized in the vaporization chamber 11 outside; a power generation device 43 disposed at a higher position than that of a tank base 19 which forms a bottom face of the tank assembly body 17; and an electromagnetic pump 24 for feeding a liquid of the tank assembly body 17 to a vaporization chamber 11. A control device 40 controls drive of the electromagnetic pump 24 by getting the control device 40 mounted on a first circuit board 37A to work with an electric power generated by the power generation device 43.SELECTED DRAWING: Figure 6

Description

The present invention relates to a steamer that ejects steam onto textile products such as clothing to smooth out wrinkles.

FIG. 8 shows the internal structure of a conventional steamer. In the figure, 201 is a steamer main body, 202 is a plug unit for supplying electric power to the steamer main body, and 203 is a stand on which the steamer main body 201 is detachably placed. The steamer main body 201 is provided with a tank 210 for storing liquid water and a base 212 in which a heater 211 as a heating means is embedded. A concave vaporization chamber 213 is formed in the base 212, and a plurality of steam holes 214 communicating with the vaporization chamber 213 are formed as openings on the lower surface of the base 212 as ejection portions. Between the tank 210 and the vaporization chamber 213, a dropping rod 216 as a movable body, a rod sleeve (silicone packing) 217 mounted on the lower part of the dropping rod 216, and a needle valve arranged facing the rod sleeve 217. A valve mechanism having 218 as a main component is provided.

The dropping rod 216 is interlocked with the steam lever 221. When the steam lever 221 is moved so that the dropping rod 216 rises, the rod sleeve 217 opens apart from the needle valve 218 and moves from the tank 210 to the vaporization chamber 213. Water can be supplied. At this time, if the vaporization chamber 213 is heated by the heater 211, the water from the tank 210 is vaporized by the heater 211 to become steam, and the steam is ejected from the steam hole 214 to the outside of the steam main body 201. To. On the contrary, when the steam lever 221 is moved so that the dropping rod 216 descends, the rod sleeve 217 comes into close contact with the needle valve 218 and closes, the supply of water from the tank 210 to the vaporization chamber 213 is cut off, and steam is generated. Steam will not be ejected from the hole 214.

As described above, the steam generation mechanism in the conventional steamer mechanically opens and closes the needle valve 218, which is the valve body, to drop the water in the tank 210 and send the water into the vaporization chamber 213 to steam. Was occurring. However, in such a structure, when the internal pressure of the vaporization chamber 213 is high, it is difficult for water to drip from the tank 210, and in order to drip water, water must be immersed in the water passage from the tank 210 to the vaporization chamber 213. There were restrictions for spewing steam, such as having to do it.

In response to these problems, the applicant of the present application has proposed the idea of incorporating an electromagnetic pump using a DC motor as a drive source into a steam iron instead of the conventional mechanical steam generation mechanism, and has already obtained a patent. In this case, by repeatedly passing and disconnecting the power to the DC motor to drive the electromagnetic pump, steam can be smoothly discharged from the ejection part regardless of the internal pressure of the vaporization chamber and regardless of the posture of the iron body. It becomes possible to spout.

Patent No. 6534886

However, the technique of Patent Document 1 is premised on a steam iron in which commercial power is constantly supplied to the iron body through a cord with a power plug. Therefore, in a cordless state where the iron body is separated from the stand during use and the power supply to the iron body is cut off, the electromagnetic pump built into the iron body cannot be operated, and steam is ejected from the ejection part. I can't.

In view of the above problems, an object of the present invention is to provide a steamer capable of smoothly ejecting steam from a ejection portion even in a cordless state in which power is not supplied to the steamer.

The steamer of the present invention has a tank for storing a liquid inside, a base provided below the tank and provided with a heating means, and a vaporization heated by the heating means in order to vaporize the liquid from the tank. A chamber, an ejection unit that ejects steam vaporized in the vaporization chamber to the outside, a power generation device arranged at a position higher than the bottom surface of the tank, and a liquid supply portion that supplies the liquid of the tank to the vaporization chamber. The liquid supply unit is controlled by the electric power generated by the power generation device.

According to the invention of claim 1, by arranging the power generation device at a position higher than the bottom surface of the tank, it is possible to prevent the power generation device from being deteriorated due to the influence of the heating temperature of the base by the heating means. In addition, even when there is no power supply to the steamer, the drive of the liquid supply unit can be controlled by using the electric power generated by the power generator, and the liquid supply unit can be used in any posture. By driving the liquid to forcibly send the liquid from the tank to the vaporization chamber, steam can be smoothly ejected from the ejection part.

According to the invention of claim 2, by driving the electromagnetic pump with the electric power from the power generation device, steam can be ejected more reliably and smoothly from the ejection portion.

According to the invention of claim 3, by arranging the liquid supply unit at a position higher than the bottom surface of the tank, it is possible to avoid the temperature rise of the liquid supply unit and to operate the liquid supply unit stably. Become.

According to the invention of claim 4, the electric power from the power generation device can also be used to drive the display unit, and even in the cordless state where the power is not supplied to the steamer, the operating state of the steamer is detected and the result is displayed. It becomes possible to display it in the section.

According to the invention of claim 5, since the power storage unit is automatically charged when the steamer is not used and not in use, steam can be smoothly ejected from the ejection portion without having to worry about charging the power storage unit. It becomes possible.

It is a right side view of the steamer in one Embodiment of this invention. Same as above, it is a perspective view seen from the right rear side of the steamer. Same as above, is a plan view of the steamer. Same as above, is a perspective view seen from the front on the right side of the steamer. Same as above, it is a perspective view seen from the right front which shows the state which the plug unit is attached to the stand. The same is the vertical sectional view of the steamer body. Same as above, it is a three-dimensional cross-sectional view showing the internal structure of the steamer main body. It is a vertical sectional view which shows the internal structure of the conventional steamer.

Hereinafter, preferred embodiments of the steamer of the present invention will be described with reference to the accompanying drawings.

1 to 7 show a steamer according to an embodiment of the present invention. Explaining the overall configuration in each of these figures, the steamer of the present embodiment is a steamer main body 1 that heats and vaporizes liquid water and ejects steam to the outside, and a steamer from a household outlet (not shown). The main components are a plug unit 2 that supplies commercial power to the main body 1, and a stand 3 that is used while being placed on the floor surface S and on which the steamer main body 1 is detachably placed. The plug unit 2 has a structure that can be attached to and detached from both the steamer main body 1 and the stand 3.

The steamer main body 1 is provided with a concave power receiving portion 5 for receiving electric power at the rear portion, while the steamer main body 1 is provided with a metal base 7 in which a heater 6 is embedded as a heating means at the lower portion. The base 7 has a structure in which a base plate 9 serving as a hanging surface member is provided on the bottom surface of the base base 8 made of a die-cast molded product, and is closely fixed to the base base 8 by a fastening member 10 fixed to the base plate 9. To. Inside the base 7, a steam chamber, that is, a vaporization chamber 11 is formed in the vicinity of the heater 6, and a plurality of steam holes 12 communicating with the vaporization chamber 11 are formed in the base plate 9 forming the lower surface of the base 7. Will be done. Further, the base 7 is provided with a steam cover 13 which is a metal plate-shaped upper lid, and the upper surface of the vaporization chamber 11 is formed by the steam cover 13 attached and fixed to the base base 8. The vaporization chamber 11 may be a separate body without being formed on the base 7. Also in that case, a heater 6 or another heating means is provided in order to heat and vaporize the liquid water in the vaporization chamber 11.

Reference numeral 15 is a resin cover provided so as to cover the side portion from the upper portion of the base 7, and 16 is provided fixedly above the cover 15 in a substantially U shape with the rear end open when viewed from the side surface. It is a formed handle. A tank assembly 17 corresponding to a tank for storing a liquid is provided from the front to the rear of the inside of the handle 16. The tank assembly 17 is composed of a resin tank cover 18 and a tank base 19, and the tank base 19 is attached and fixed so as to cover the bottom opening of the tank cover 18 so as to be inside the tank assembly 17. A liquid storage space 20 is formed.

Reference numeral 21 denotes a water injection port provided in the front portion of the tank assembly 17 and directly communicating with the storage space 20 described above. A water injection port lid 22 that allows the water injection port 21 to be manually opened and closed is provided at the front portion of the handle 16 facing the water injection port 21, and the water injection port lid 22 is raised toward the front side to open the water injection port 21. From here, liquid water is stored in the tank assembly 17, and unnecessary water in the tank assembly 17 is discarded. Further, in the upper storage space 23 separated from the storage space 20 by the vertical wall 18A formed behind the tank cover 18 inside the steamer main body 1, the water stored in the storage space 20 of the tank assembly 17 is stored in the storage space 20. An electromagnetic pump 24 for supplying to the vaporization chamber 11 heated by the heater 6 is arranged. A suction pipe 25 communicating with the storage space 20 of the tank assembly 17 and a discharge pipe 26 communicating with the low temperature liquid inflow prevention mechanism 47 described later are connected to the electromagnetic pump 24, respectively, and the suction pipe 25 is formed on the vertical wall 18A. It is connected to the connecting pipe 27 in a liquid-tight state, and extends from the upper accommodating space 23 of the electromagnetic pump 24 to the water storage space 20. As a result, no matter what posture the steamer main body 1 is used in, the water stored in the storage space 20 does not enter the upper storage space 23 in which the electromagnetic pump 24 is arranged, and the storage space 20 is operated during the operation of the electromagnetic pump 24. The water sucked into the electromagnetic pump 24 through the suction pipe 25 and the connecting pipe 27 can be sent out to the liquid inflow prevention mechanism 47 at low temperature through the discharge pipe 26.

The handle 16 is composed of two parts, a handle base 28 made of resin and a handle cover 29, and is located at the uppermost portion of the steamer main body 1 to form a rod-shaped grip portion 31 extending from the front to the rear. The grip portion 31 has a cavity 33 between the grip portion 31 and the abdomen 32 of the steamer main body 1, and at the rear portion of the grip portion 31, a hand is inserted into the cavity 33 from the rear portion of the steamer main body 1 to hold the grip portion 31. An opening 34 communicating with the cavity 33 is formed so that it can be gripped by. That is, the grip portion 31 here has a shape in which the rear portion is not connected to any portion of the steamer main body 1 and an opening 34 is formed and opened. Further, the abdominal portion 32 referred to here refers to a flat central upper surface portion of the steamer main body 1 facing the grip portion 31, and is formed as a base portion 28A of the handle base 28 in the present embodiment. In addition to the base 28A, the handle base 28 includes a connecting portion 28B that rises in a U shape on the front side of the base 28A, and an extending portion 28C that extends rearward from the connecting portion 28B and forms the lower surface portion of the grip portion 31. By covering the extension portion 28C with the handle cover 29, the grip portion 31 of the steamer main body 1 is configured.

On the front side of the grip portion 31 located at the upper part of the steamer main body 1, a temperature setting / off button as a first operating body that can both set the temperature of the base 7 and turn on / off the power as an operating body that can be manually operated. 35 and a steam amount setting button 36 as a second operating body for setting the flow rate of steam ejected from the steam hole 12 are respectively arranged. The buttons 35 and 36 for these operations are mounted on the first substrate 37A arranged in front of the inside of the grip portion 31. The number of operating bodies is not limited to two as in the present embodiment, and may be operating bodies other than the push type. In addition, any function may be assigned to any operating body.

In addition to the temperature setting / off button 35 and the steam amount setting button 36, the first substrate 37A includes a temperature indicator lamp 38 provided on the upper front side of the grip portion 31 and arranging a plurality of LEDs, and turning on / off the power. A buzzer 39 as a notification unit that notifies the base 7 that the set temperature has been reached by sound, a heater 6 that is a load of the steamer main body 1, an electromagnetic pump 24, and a control device 40 that controls the operation of the temperature indicator lamp 38. Etc. are installed. The temperature display lamp 38 displays whether or not the temperature set by the temperature setting / off button 35 and the temperature of the base 7 detected by the temperature detecting means 41 have reached the set temperature, and the operating state of the steamer main body 1 Corresponds to the display unit that displays. Further, the temperature detecting means 41 is attached and fixed to the base 7 inside the steamer main body 1 as a sensor unit for displaying the operating state of the steamer main body 1.

Inside the grip portion 31, a second substrate 37B for power supply is arranged behind the first substrate 37A for control. These substrates 37A and 37B are electrically connected to each other by wiring 42. In addition to the external commercial power from the plug unit 2, the second substrate 37B receives the power generation device 43 having a power generation function inside the steamer main body 1 and the power generated by the power generation device 43, and each part of the steamer main body 1. A power supply circuit 44 or the like that outputs appropriate operating power is installed in the system. The number of boards 37A and 37B incorporated in the steamer main body 1 and which components are mounted on which boards 37A and 37B are not particularly limited.

The power generation device 43 includes a primary battery (battery) or a secondary battery for supplying power. Preferably, if the steamer main body 1 is supplied with commercial power from the plug unit 2 in an unused state when each part of the steamer main body 1 is not operating, the charging circuit uses the commercial power. The power generation device 43 may be configured by a power storage unit that combines a secondary battery and a charging circuit so that the secondary battery can be automatically charged.

The power supply circuit 44 receives the electric power generated from the power generation device 43 in a cordless state in which the commercial electric power from the plug unit 2 is not supplied to the steamer main body 1, and the temperature indicator lamp 38 mounted on the first substrate 37A and the like. , The operating power required to operate each of them is sent to the buzzer 39, the control device 40, etc. through the wiring 42, and the electromagnetic pump 24 is also passed through another wiring 45 routed inside the steamer main body 1. It sends out the operating power required to operate the pump 24. A part or all of the functions of the power supply circuit 44 may be incorporated into the power generation device 43.

When the operating power is supplied from the power supply circuit 44, the control device 40 has a temperature based on the set temperature based on the operation signal from the temperature setting / off button 35 and the temperature of the base 7 based on the detection signal from the temperature detecting means 41. Control drive to the indicator lamp 38 is performed. At this time, the temperature indicator lamp 38 is similarly turned on or blinks by being supplied with the operating power from the power supply circuit 44. Further, in the control device 40, when the operating power is supplied from the power supply circuit 44, the steam of the flow rate set based on the operation signal from the steam amount setting button 36 is ejected to the outside of the steamer main body 1 through the steam hole 12. In addition, the drive of the electromagnetic pump 24 is controlled. At this time, the electromagnetic pump 24 is also configured to be operated according to the set steam flow rate by being supplied with the operating power from the power supply circuit 44.

In the liquid passage 46 from the tank assembly 17 to the vaporization chamber 11, the suction pipe 25, the discharge pipe 26, the electromagnetic pump 24 including the connecting pipe 27, and the base 7 are in a state of being lower than the vaporization temperature. A low temperature liquid inflow prevention mechanism 47 for preventing the liquid from flowing into the vaporization chamber 11 is incorporated therein. The electromagnetic pump 24 supplies water from the tank assembly 17 to the vaporization chamber 11, and is a liquid supply unit that changes the flow rate of water supplied to the vaporization chamber 11 according to the steam flow rate set by the steam amount setting button 36. As a result, it is arranged in the upper accommodation space 23 inside the steamer main body 1. As a specific configuration of the electromagnetic pump 24, for example, a DC motor drive type pump disclosed in Patent Document 1 may be adopted. In this case, the control device 40 drives and controls the electromagnetic pump 24 so as to repeatedly connect and disconnect the electromagnetic pump 24, so that a predetermined amount of water can be sent from the tank assembly 17 to the vaporization chamber 11. The amount of water supplied from the electromagnetic pump 24, and thus the steam flow rate from the steam hole 12, can be arbitrarily increased or decreased by changing the timing of power transmission / disconnection to the electromagnetic pump 24.

On the other hand, the low temperature liquid inflow prevention mechanism 47 mainly includes a bimetal 51 as a heat-sensitive responding body that deforms by sensing the temperature of the base 7, and a valve member 52 that opens and closes the passage 46 in response to the bimetal 51. And. The bimetal 51 is housed in a concave bimetal storage chamber 53 provided on the upper surface of the base base 8, and when the base 7 is lower than the vaporization temperature of the liquid, the bimetal 51 returns to a returning state and closes the passage 46. While the valve member 52 moves, when the base 7 reaches the liquid vaporization temperature or higher, the bimetal 51 is in an inverted state and the valve member 52 moves in the direction of opening the passage 46. At this time, if the above-mentioned electromagnetic pump 24 is operating, water from the tank assembly 17 is forced into the vaporization chamber 11 through the low temperature liquid inflow prevention mechanism 47 regardless of the posture of the steamer main body 1. The liquid is surely dropped into the vaporization chamber 11.

Inside the steamer body 1, between the tank base 19 forming the bottom surface of the tank assembly 17 and the upper surface of the base 7 heated by the heater 6, the temperature detecting means mounted on the upper surface of the steam cover 13. A lower accommodating space 54 is formed in which the cover 15 covers the 41, the low temperature liquid inflow prevention mechanism 47, and the like. In the lower accommodation space 54 between the tank base 19 and the base 7, the upper surface of the cover 15 is interposed as a heat shield portion 15A, and the bottom surface of the base 7 as shown in FIGS. 6 and 7 is oriented horizontally. In the state, that is, in the state where the steamer main body 1 is horizontal, the electromagnetic pump 24 and the power generation device 43 are all arranged at a high position above the tank base 19 and the lower accommodation space 54.

By arranging the electromagnetic pump 24 and the power generation device 43 at a position higher than the tank base 19, a lower accommodating space 54 for blocking heat from the base 7 is interposed between the base 7 and the electromagnetic pump 24, and electromagnetic waves are generated. The temperature rise of the pump 24 and the power generation device 43 is avoided. Further, since the heat shield portion 15A of the cover 15 is also arranged in the lower accommodation space 54, the heat shield portion 15A also effectively blocks the heat from the base 7, and the temperature of the electromagnetic pump 24 and the power generation device 43 rises. Can be further avoided. In particular, since the power generation device 43 is provided at the rearmost portion of the grip portion 31 of the handle 16 farthest from the base 7, the thermal influence from the base 7 on the power generation device 43 can be avoided to the maximum.

As a modification, the upper surface of the tank assembly 17 facing the base 28A of the handle base 28 may be formed in a concave shape, and the electromagnetic pump 24 may be accommodated and arranged therein. In this case, the heat from the base 7 can be more effectively cut off by utilizing the storage space 20 of the tank assembly 17 interposed between the electromagnetic pump 24 and the base 7. Such an effect is similarly exhibited in the heat generating device 43 in which the storage space 20 is interposed between the base 7 and the base 7.

The plug unit 2 mainly includes a flexible power supply cord 61 and a power supply plug 62 provided at the base end of the power supply cord 61. Although not shown, a power plug that can be inserted into and removed from a household outlet is provided at the tip of the power cord 61. In the present embodiment, the power supply plug 62 with the power cord 61 can be attached to and detached from both the steamer main body 1 and the stand 3.

The power supply plug 62 is provided with a cordless changeover switch 63 that allows the power supply plug 62 to be manually fitted or not fitted into the recess 5 of the steamer body 1. The cordless changeover switch 63 is provided so as to be slidable back and forth on the upper surface side of the power supply plug 62, and when the power supply plug 62 as shown in FIG. 5 is mounted on the stand 3, the plug unit 2 is mounted from the steamer main body 1. In order to use the steamer main body 1 in the removed cordless state, the cordless changeover switch 63 is moved forward on one side to release the mating between the steamer main body 1 and the power feeding plug 62. On the other hand, in order to use the steamer main body 1 with the power supply plug 62 removed from the stand 3 and the plug unit 2 attached to the steamer main body 1 with a cord, the cordless changeover switch 63 is moved to the rear side on the other side. Then, the steamer main body 1 and the power feeding plug 62 are fitted. At this time, the front part of the power supply plug 62 is attached to the recess 5 of the steamer main body 1, but the rear part of the power supply plug 62 including the cordless changeover switch 63 is exposed without being surrounded by the recess 5, and the user can use it at any time. However, the cordless changeover switch 63 can be manually operated. The recess 5 of the steamer body 1 is provided with a pair of power receiving terminals 64 that can be electrically connected to the power feeding terminals (not shown) of the plug unit 2.

The pedestal 3 is provided at the main body mounting portion 66 formed so as to be inclined with respect to the floor surface S and behind the main body mounting portion 66 so that the front of the steamer main body 1 is mounted obliquely upward. It is provided with a concave plug accommodating portion 67 to be provided, and a cord drawer portion 68 provided at the rear portion of the pedestal 3 to pull out the power cord 61 to the outside of the pedestal 3 when the power feeding plug 62 is attached to the plug accommodating portion 67. There is. When the power supply plug 62 is inserted from the open front side of the plug accommodating portion 67, the power supply plug 62 is fitted and held in the plug accommodating portion 67, while when the power supply plug 62 is pulled out toward the front side from this state, the power supply plug 62 And the plug accommodating portion 67 are disengaged from each other.

The power feeding plug 62 includes a fitting claw 71 and a shutter member 72, respectively, in addition to the cordless changeover switch 63 described above. The fitting claw 71 is constantly urged by a first elastic member such as a spring provided inside the power feeding plug 62 so as to protrude from the upper surface of the power feeding plug 62. When the cordless changeover switch 63 is moved to the "cordless" side in front of one side against the urging of the first elastic member, the protruding length of the fitting claw 71 from the upper surface of the power feeding plug 62 is reduced. It has become. As a result, when the cordless changeover switch 63 is on the "cordless" side, the protruding length of the fitting claw 71 from the upper surface of the power feeding plug 62 becomes small. By accommodating and holding in the accommodating portion 67, the recess 5 of the steamer main body 1 mounted on the main body mounting portion 66 of the pedestal 3 can be inserted and removed from the power feeding plug 62 without interfering with the fitting claw 71, and the steamer main body can be inserted and removed. 1 can be used cordlessly.

On the other hand, when the cordless changeover switch 63 is moved to the "cord" side behind the other side, only the urging force of the first elastic member acts on the fitting claw 71, so that the fitting claw 71 from the upper surface of the power feeding plug 62 The overhang length of is increased compared to the case of "cordless". Therefore, when the cordless changeover switch 63 is on the "cord" side, when the recess 5 of the steamer body 1 is inserted into the power feeding plug 62, the fitting claw 71 that greatly protrudes due to the urging force of the first elastic member becomes the recess 5. The steamer body 1 can be used with the cord attached to the plug unit 2 unless the cordless changeover switch 63 is switched to the "cordless" side by fitting to the receiving portion (not shown) formed in. Become.

In the resin shutter member 72, the conductive power supply terminals (not shown) provided inside the power supply plug 62 are not exposed from the pair of power supply holes 73 formed in front of the power supply plug 62. Similarly, it is constantly urged by a second elastic member (not shown) such as a torsion spring provided inside the power feeding plug 62. Then, in the present embodiment, when the steamer main body 1 is used either cordlessly or with a cord, the power supply terminal is exposed from the power supply hole 73 when the recess 5 of the steamer main body 1 is inserted into the power supply plug 62. 2 The shutter member 72 rotates against the urging force of the elastic member, and the power receiving terminal 64 of the steamer main body 1 passes through the power feeding hole 65A of the power feeding plug 62 and comes into contact with the power feeding terminal 88. As a result, power can be supplied from the household outlet to the steamer main body 1 via the plug unit 2.

Next, the operation of the steamer having the above configuration will be described. The water injection palate 22 provided in the steamer main body 1 is opened and closed to accommodate a predetermined amount of water in the storage space 20 of the tank assembly 17. Subsequently, the power supply plug 62 of the plug unit 2 is fitted and accommodated in the plug accommodating portion 67 of the pedestal 3, and the steamer main body 1 is mounted on the main body mounting portion 66 of the pedestal 3, or the pedestal 3 is not used. , The power supply plug 62 is inserted into the recess 5 of the steamer main body 1 and fitted, and the commercial power supplied from the household outlet is supplied to the steamer main body 1 via the power supply plug 62.

In the off state where the temperature setting / off button 35 and the steam amount setting button 36 are not operated immediately after the power is supplied, the power storage unit, which is the power generation device 43, is automatically charged by the commercial power supplied to the steamer main body 1. Therefore, when charging the power generation device 43, the user does not have to bother to operate an operating body such as the temperature setting / off button 35 or the steam amount setting button 36. Further, in the off state, the heater 6 and the temperature display lamp 38 are not energized, but the remaining battery level of the power generation device 43 may be displayed on the temperature display lamp 38 or another display unit.

When the steamer main body 1 is used with the above-mentioned cord, the temperature setting / off button 35 is pressed from the off state to set the temperature according to the cloth of clothing that is the target of steam ejection, and then the steamer main body 1 Inside, charging of the power generation device 43 is completed. Further, the control device 40 controls the power interruption of the heater 6 so that the temperature of the base 7 detected by the temperature detecting means 41 approaches the temperature set by the temperature setting / off button 35, and the base including the vaporization chamber 11. 7 is heated. After that, when the base 7 reaches a certain temperature or higher as the heater 6 is energized, the bimetal 51 stored in the bimetal storage chamber 53 of the base base 8 is inverted, and the passage 46 is opened inside the liquid inflow prevention mechanism 47 at low temperature. The valve member 52 moves in the direction of movement. In this series of processes, the control device 40 blinks one LED in the temperature indicator lamp 38 corresponding to the set temperature, and when the temperature of the base 7 detected by the temperature detecting means 41 reaches the set temperature. , A control signal for driving and controlling the temperature indicator lamp 38 is sent so as to switch the blinking LED to the lighting operation.

Here, when the user uses the steam function, when the steam amount setting button 36 is pushed with a finger from the initial position while holding the grip portion 31 by hand, the steam amount setting button 36 is moved to the pushed position. The corresponding steam flow rate is set, and an operation signal corresponding to the steam flow rate is sent to the control device 40. The control device 40 receives the operation signal from the steam amount setting button 36 and sends out a control signal for controlling the drive of the electromagnetic pump 24 so that the steam of the set flow rate is ejected from the steam hole 12. .. As a result, the electromagnetic pump 24 is repeatedly disconnected and disconnected at the timing corresponding to the set steam flow rate, and the water sucked from the storage space 20 of the tank assembly 17 through the suction pipe 25 and the connecting pipe 27 is passed through the discharge pipe 26. It can be sent to the liquid inflow prevention mechanism 47 at low temperature. Therefore, in this case, regardless of the posture in which the steamer main body 1 is used, water surely reaches the heated vaporization chamber 11 and is vaporized there, and the cloth for clothing is passed through the steam hole 12 from the bottom surface of the steam main body 1. Steam can be ejected at the flow rate set to.

When the user uses the dry function, the control means 40 stops sending the control signal to the electromagnetic pump 24 when the steam amount setting button 36 is released from the steam amount setting button 36 and the steam amount setting button 36 is returned to the initial position. To do. In response to this, the electromagnetic pump 24 stops its operation, and the delivery of water from the storage space 20 of the tank assembly 17 to the vaporization chamber 11 is cut off. Therefore, in this case, the steamer main body 1 can be used as a dry steamer in which steam does not eject from all the steam holes 12.

On the other hand, when the steamer main body 1 is used cordlessly, each part of the steamer main body 1 can be operated in the same manner as when the steamer main body 1 has a cord, using the power generation device 43 as a power source, except for the heater 6 which consumes a large amount of power.

Specifically, when the steamer main body 1 becomes cordless, the power supply circuit 44 mounted on the second board 37B receives the electric power generated from the power generation device 43, and the temperature indicator lamp 38 mounted on the first board 37A. The operating power is supplied to the buzzer 39, the control device 40, and the like through the wiring 42. The control device 40 operated by this drives the temperature display lamp 38 described above by the set temperature based on the operation signal from the temperature setting / off button 35 and the temperature of the base 7 based on the detection signal from the temperature detecting means 41. A control signal for control is transmitted, and one LED in the temperature indicator lamp 38 lights up or blinks according to the control signal by the operating power given from the power supply circuit 44. Regarding this point, in the conventional steamer, all the display units are turned off and not displayed during cordless use, and the operating state of the steamer cannot be confirmed on the display unit. However, in the present embodiment, even during cordless use. Using the electric power from the power generation device 43, the temperature of the base 7, which is the operating state of the steamer, can be continuously displayed and confirmed by the temperature indicator lamp 38 provided on the upper surface of the steamer main body 1.

Further, in the state where the steamer main body 1 is cordless, the power supply circuit 44 receives the electric power generated from the power generation device 43, and also supplies the operating power to the electromagnetic pump 24 through the wiring 45. At this time, when the steam amount setting button 36 is pushed and operated with a finger, the steam flow rate corresponding to the pushed position is set, and an operation signal corresponding to the push operation signal is sent to the control device 40, the control device 40 sets the steam amount. In response to the operation signal from the button 36, a control signal for controlling the drive of the electromagnetic pump 24 is sent so that the steam of the set flow rate is ejected from the steam hole 12. As a result, the electromagnetic pump 24 is repeatedly disconnected and disconnected at the timing corresponding to the set steam flow rate, and the water sucked from the storage space 20 of the tank assembly 17 can be sent out to the liquid inflow prevention mechanism 47 at low temperature. It becomes. Therefore, if the bimetal 51 is inverted due to the residual heat of the base 7, the passage 46 is opened inside the liquid inflow prevention mechanism 47 at low temperature, so that the tank assembly can be used in any posture regardless of the posture of the steamer main body 1. Water surely reaches the heated vaporization chamber 11 from the storage space 20 of the solid body 17 and is vaporized there, and the steam of the flow rate set by the steam amount setting button 36 can be ejected from the steam hole 12.

As described above, the steamer of the present embodiment has a tank assembly 17 as a tank for storing the liquid inside, and a base 7 provided below the tank assembly 17 by burying a heater 6 as a heating means. The vaporization chamber 11 heated by the heater 6 in order to vaporize the liquid from the tank assembly 17, the steam hole 12 as a ejection part for ejecting the steam vaporized in the vaporization chamber 11 to the outside, and the tank assembly. The steamer main body 1 is provided with a power generation device 43 arranged at a position higher than the tank base 19 forming the bottom surface of the 17 and an electromagnetic pump 24 as a liquid supply unit for supplying the liquid of the tank assembly 17 to the vaporization chamber 11. The control device 40 mounted on the first substrate 37A is operated by the electric power generated by the power generation device 43, and the control device 40 controls the drive of the electromagnetic pump 24.

In this case, by arranging the power generation device 43 at a position higher than the tank base 19 forming the bottom surface of the tank assembly 17, it is possible to prevent the power generation device 43 from deteriorating due to the influence of the heating temperature of the base 7 by the heater 6. be able to. Further, even in a cordless state where there is no power supply to the steamer and thus the steamer main body 1, the drive of the electromagnetic pump 24 can be controlled by using the electric power generated by the power generation device 43, and what kind of posture the steamer main body 1 is in. By driving the electromagnetic pump 24 to forcibly send the liquid from the tank assembly 17 to the vaporization chamber 11, steam can be smoothly ejected from the steam hole 12.

Further, the liquid supply unit of the present embodiment is composed of an electromagnetic pump 24, and uses the electric power from the power generation device 43 to apply the operating power from the power supply circuit 44 to the electromagnetic pump 24 to drive the electromagnetic pump 24. Therefore, the liquid contained in the storage space 20 in the tank assembly 17 is sent to the vaporization chamber 11.

In this case, by driving the electromagnetic pump 24 with the electric power from the power generation device 43, steam can be more reliably and smoothly ejected from the steam hole 12.

Further, in the present embodiment, the electromagnetic pump 24 serving as the liquid supply unit is arranged inside the steamer main body 1 at a position higher than the tank base 19 forming the bottom surface of the tank assembly 17.

In this case, by arranging the electromagnetic pump 24 at a position higher than the tank base 19, it is possible to avoid the temperature rise of the electromagnetic pump 24 and to operate the electromagnetic pump 24 in a stable manner.

Further, in the present embodiment, as the operating state of the steamer main body 1, a temperature detecting means 41 as a sensor unit for detecting the temperature of the base 7 and a temperature display lamp 38 as a display unit for displaying the temperature of the base 7 are further provided. The temperature indicator lamp 38 is operated according to the temperature of the base 7 by the control drive of the control device 40 by the temperature detecting means 41 using the power from the power generation device 43.

In this case, the electric power from the power generation device 43 can also be used to drive the temperature indicator lamp 38, and the temperature of the base 7 which is the operating state of the steamer main body 1 is detected even in the cordless state where the power is not supplied to the steamer main body 1. Then, the result can be displayed on the temperature display lamp 38.

Further, the power generation device 43 of the present embodiment is composed of a power storage unit that can automatically charge the steamer main body 1 in an off state when it is not in use.

In this case, since the power storage unit as the power generation device 43 is automatically charged when the steamer main body 1 is not used and is not in use, steam is steamed from the steam hole 12 without worrying about charging the power storage unit. Can be spouted smoothly.

As described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention. The name of the present invention, "steamer", is applied to any device that ejects steam to smooth out wrinkles such as clothes, for example, to eject steam from a distant position as shown in the present embodiment. Not only suitable steamers, but also steam irons suitable for spouting steam while ironing by pressing the hanging surface of the base against clothing are included. Further, various sensor units other than the temperature detecting means 41 may be used to drive and control the operation of the display unit, and the display unit is not limited to the LED, and various other display elements and indicators can be used.

6 Heater (heating means)
7 Base 11 Vaporizing chamber 12 Steam hole (spouting part)
17 Tank assembly (tank)
24 Electromagnetic pump (liquid supply unit)
38 Temperature indicator lamp 41 Temperature detection means (sensor unit)
43 Power generation device (storage unit)

Claims (5)

A tank that stores liquid inside and
A base provided below the tank and provided with heating means,
In order to vaporize the liquid from the tank, the vaporization chamber heated by the heating means and
An ejection part that ejects steam vaporized in the vaporization chamber to the outside,
A power generator located higher than the bottom of the tank and
A liquid supply unit that supplies the liquid in the tank to the vaporization chamber is provided.
A steamer characterized in that the drive of the liquid supply unit is controlled by the electric power generated by the power generation device. The liquid supply unit is composed of an electromagnetic pump.
The steamer according to claim 1, wherein the liquid in the tank is sent to the vaporization chamber by driving the electromagnetic pump using the power generation device. The steamer according to claim 1 or 2, wherein the liquid supply unit is arranged at a position higher than the bottom surface of the tank. A sensor unit that detects the operating state of the steamer and
A display unit for displaying the operating state of the steamer is further provided.
The steamer according to any one of claims 1 to 3, wherein the display unit is operated by a control drive by the sensor unit using the power generation device. The steamer according to any one of claims 1 to 4, wherein the power generation device includes a power storage unit that can be automatically charged when the steamer is not in use.

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