KR102360834B1 - Steam generator - Google Patents

Abstract

The present invention discloses a steam generator, and the present invention is configured to be connected through an inclined passage provided on the outside of the tank connecting the water supply tank and the heating tank of the tank. Accordingly, when water is heated in the heating tank, the heated water It prevents backflow into the water supply tank to prevent the temperature of the water in the water supply tank from rising, and blocks the lime component generated in the heating tank from flowing into the water supply tank, and the lime component is fixed to the water level sensor provided in the water supply tank and the water level sensor This is to prevent the deterioration of the water inflow control function according to the water level measurement of the water level sensor while solving the problem of causing an operation error.

Description

Steam generator

The present invention relates to a steam generator, and more particularly, to a steam generator capable of preventing lime components generated by steam generation in a tank heating tank from flowing into a water supply tank and affecting a water level sensor.

In general, various devices are being developed that can make the lives of modern people more and more abundant, in which individual desires for health and beauty are increasing. Among them, devices that allow individuals to conveniently enjoy thermal treatment, massage, sauna, or steam bath at home, for example, a sauna device, are being developed.

Most of the conventional sauna devices have a form in which all or part of the human body has to go into the device, but these devices are inconvenient to move and install, and the production cost is high, so you can enjoy them only by paying a high cost.

Another type of steam generator is a steam generator that allows you to enjoy a sauna conveniently by filling up steam in an isolated space such as a shower booth at home. It condensed and dripped, so it was difficult to expect the sauna effect.

That is, the generated steam of the steam generator installed in the bathroom booth is discharged to the steam shower through the steam nozzle, and this steam generator constitutes the tank 100 in the interior of the main body as shown in FIGS. 1 to 4, The tank 100 is divided into a water supply tank 102 and a heating tank 103 through a partition wall 101, and the water supply tank 102 is provided with water level sensors 104a, 104b and a solenoid valve 105a. A heater 106 and a steam outlet pipe 107 are configured in the water supply pipe 105 and the heating tank 103 , and the water supplied to the water supply tank 102 is supplied to the lower end of the partition wall 101 . As it flows into the heating tank 103 through the provided flow path 101a, it is evaporated during the heating operation of the heater 106 to generate steam.

At this time, the water level sensor 104a configured in the water supply tank 102 as shown in the accompanying FIGS. As shown, the water level sensor 104b configured in the water supply tank 102 operates as a mechanical mechanism by the pressure of water to detect the water level by a float method.

That is, the capacitive type water level sensor 104a constitutes a plurality of contact terminals a1 and a2, and the float type water level sensor 104b has a fixing member b1 and a rotating member b2 and connecting them. The hinge (h) is included.

Accordingly, as in the attached FIG. 1, when the capacitive water level sensor 104a is applied to the water supply tank 102, the solenoid valve 105a is closed when water comes into contact with the water level sensor 104a. to stop the supply of water to the water supply tank 102 through the water supply pipe 105, and when the water does not come into contact with the water level sensor 104a, the solenoid valve 105a is opened and the water supply through the water supply pipe 105 The water supply to the tank 102 can be resumed.

However, as shown in the accompanying FIG. 2 , when steam is generated while water is evaporated according to the heating operation of the heater 106 in the heating tank 103, the lime component contained in the water is generated, and this lime component is formed in the partition wall ( After flowing into the water supply tank 102 through the flow path 101a of 101), a phenomenon (part 'P' in FIG. 2 ) that is fixed to the surface of the capacitive water level sensor 104a may result, and this may result in the adhesion of the water level sensor 104a Due to the lime component, the capacitive water level sensor 104a blocks contact with water, and there is a problem in that a detection error occurs because there is no water even if a certain amount of water is filled in the water supply tank 102, such detection The error is that while the opening of the solenoid valve 105a continues, water is continuously supplied through the water supply pipe 105 and flows into the heating tank 103 through the flow path 101a of the partition wall 101, and finally the heating bath 103 ) through the steam outlet pipe 107 had no choice but to cause a problem of overflowing to the outside of the tank 100 .

On the other hand, when the float type water level sensor 104b is applied to the water supply tank 102, as shown in FIG. 3, when the water level sensor 104b is submerged in water, the solenoid valve 105a is closed and the water supply pipe When the supply of water to the water supply tank 102 through 105 is stopped, and the water level sensor 104a is not submerged in water, the solenoid valve 105a is opened, and the water supply tank 102 ) so that water supply can be resumed.

However, as shown in the accompanying FIG. 4, when the steam is generated as water evaporates according to the heating operation of the heater 106 in the heating tank 103, the lime component contained in the water is generated, and this lime component is formed in the partition wall ( After flowing into the water supply tank 102 through the flow path 101a of 101), a phenomenon of being fixed to the hinge h of the float type water level sensor 104b (the 'Q' part in FIG. 4) may result, Accordingly, rotation of the rotating member b2 constituting the water level sensor 104b due to the adhering lime component is limited due to the lime component adhering to the hinge h, and the water level in the water supply tank 102 is low There is a problem in that a detection error occurs, and this detection error causes the heater 106 of the heating tank 103 to heat while the supply of water through the water supply pipe 105 is stopped while the closing of the solenoid valve 105a continues. When the water is not evaporated, steam is not generated properly, and when the heater 106 is heated in a state where there is no water in the heating tank 103, the temperature in the heating tank 103 rises rapidly, resulting in a fire or explosion. There was a problem that caused the risk of safety accidents such as

Accordingly, the present invention is to improve the conventional problems as described above, and by connecting the water supply tank and the heating tank of the tank through an inclined passage provided on the outside of the tank, the heating is performed when the water is heated in the heating tank. Prevents water from flowing back into the water supply tank and prevents the temperature of the water in the water supply tank from rising An object of the present invention is to provide a steam generator that can solve the problem that the water level sensor causes an operation error.

The steam generator of the present invention for achieving the above object constitutes a water tank of the steam generator that is divided into a water supply tank in which a water level sensor is installed and a heating tank in which a heater is installed through a partition wall, and the water supply tank and the heating tank are outside the water tank It is connected with an inclined tube body in

In addition, the inclined pipe body, a first flow pipe connected to the water supply tank side having a first height; a second flow path pipe connected to the heating tank side and having a second height lower than the first height of the first flow path pipe; and a connecting inclined pipe connecting the first and second flow paths. constituted including .

In addition, the water level sensor is a capacitive type sensor or a float type sensor.

As described above, the present invention is configured to be connected through an inclined passage provided on the outside of the tank connecting the water supply tank and the heating tank of the tank, and through this, the heated water is prevented from flowing back into the water supply tank when water is heated in the heating tank Not only does it prevent the temperature of the water in the water supply tank from rising, but it also blocks the lime component generated in the heating tank from flowing into the water supply tank, and the lime component is fixed to the water level sensor provided in the water supply tank and causes the water level sensor to malfunction. While solving the problem, the effect of preventing the water inflow control function according to the water level measurement of the water level sensor from being deteriorated can be expected.

1 is a schematic cross-sectional view showing a state in which water is normally supplied to a water tank of a steam generator to which a conventional capacitive water level sensor is applied.
2 is a schematic cross-sectional view showing a state in which water is abnormally supplied to a water tank of a steam generator to which a conventional capacitive water level sensor is applied.
3 is a schematic cross-sectional view showing a state in which water is normally supplied to a water tank of a steam generator to which a conventional float type water level sensor is applied.
4 is a cross-sectional schematic view showing a state in which water is abnormally supplied to a water tank of a steam generator to which a conventional float type water level sensor is applied.
5 is a schematic cross-sectional view showing a water tank of a steam generator to which a capacitive water level sensor is applied according to an embodiment of the present invention, showing a full water level;
6 is a cross-sectional schematic view showing a water shortage state in a water tank of a steam generator to which a capacitive water level sensor is applied according to an embodiment of the present invention.
7 is a cross-sectional schematic view showing a state in which the water tank of the steam generator to which the float type water level sensor is applied according to an embodiment of the present invention is at a full water level;
8 is a cross-sectional schematic view showing a state in which water is insufficient in the water tank of a steam generator to which a float type water level sensor is applied according to an embodiment of the present invention.

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

5 is a cross-sectional schematic view showing a water tank of a steam generator to which a capacitive water level sensor is applied as an embodiment of the present invention is at full water level, and FIG. 6 is a steam generator to which a capacitive water level sensor is applied as an embodiment of the present invention It is a schematic cross-sectional view showing a water shortage state in the water tank of the generator, and FIG. 7 is a cross-sectional schematic view showing the water tank of the steam generator to which the float type water level sensor is applied as an embodiment of the present invention is in a full water level, and FIG. As an embodiment of the present invention, a schematic cross-sectional view showing a water shortage in a water tank of a steam generator to which a float type water level sensor is applied is shown.

4 to 8, the steam generator according to the embodiment of the present invention includes a water tank 13 through which the water tank 100 is provided with a water level sensor 12a or 12b through a bulkhead 11, and In a state in which the heater 14 is installed in the heating tank 15 , the water supply tank 13 and the heating tank 15 are connected to the first and second flow passage pipes 21 from the outside of the water tank 10 . ) (22) and the inclined tube body (20) including the connecting inclined tube (23) is configured to be connected.

The first flow pipe 21 has a first height h1 and is connected to the water supply tank 13 side of the water tank 10 .

The second flow pipe 22 has a second height h2 higher than the first height h1 of the first flow path pipe 21 (h1 > h2), and the heating tank of the water tank 10 is (15) is connected to the side.

The connecting inclined pipe 23 is configured to connect the first and second flow passage pipes 21 and 22, and the first and second heights h1 of the first and second flow passage pipes 21 and 22 ( It is configured to maintain the inclined state by h2).

Here, as the water level sensor, a conventional capacitive water level sensor 12a or a conventional float type water level sensor 12b is applied, but it is not necessarily limited thereto. It is also possible to selectively apply known sensors for

In addition, a water supply pipe 16 to which a solenoid valve 16a is applied is usually connected to the water supply tank 13 of the water tank 10 , and a heating tank 15 of the water tank 10 is usually connected to a heating tank 15 . When steam is generated inside (15), a steam outlet pipe 17 is formed for draining it to the outside.

As described above, the steam generator according to the embodiment of the present invention includes a water tank 10 divided into a water supply tank 13 and a heating tank 15 by a partition wall 11 as shown in FIGS. 5 and 6 . A capacitive water level sensor (12a) is applied to the water supply tank (13), while the heater (14) is built into the heating tank (15) by opening the solenoid valve (16a) to the water supply pipe Water is supplied to the water supply tank 13 through (16).

Then, the water supplied to the water supply tank 13 passes through the first flow path pipe 21, the connecting inclined pipe 23 and the second flow path pipe 22 of the inclined pipe body 20 having a first height h1. As it is supplied to the inside of the heating bath 13 through the heating bath 13, the water level in the heating bath 13 rises.

At this time, in a state in which the water level of the heating tank 13 is raised, the water level of the water supply tank 13 also rises, so that water is formed in a plurality of contact terminals a1 and a2 in the capacitive water level sensor 12a. ), the water level sensor 12a generates a water detection signal according to the water level rise, and the closing operation of the solenoid valve 16a is made according to the water detection signal generated from the water level sensor 12a, The water supply to the water supply tank 13 through (16) is stopped.

Here, although it has been described to control the opening and closing operation of the solenoid valve 16a according to the water detection signal of the water level sensor 12a, the opening and closing operation of the solenoid valve 16a can be controlled by a control unit (not shown). Accordingly, the water detection signal of the water level sensor 12a may be configured to be output to the control unit.

And, in a state in which water is supplied from the water supply tank 13 to the heating tank 15 through the inclined tube body 20 as described above, when the heater 14 in the heating tank 15 performs a heating operation, the According to the heating operation of the heater 14 , water is evaporated to generate steam, and the steam is discharged to the outside through the steam outlet pipe 17 of the heating tank 15 .

At this time, when water is evaporated from the heating operation of the heater 14 to generate steam, the lime component contained in the water is generated in the heating tank 15 , and this lime component is passed through the inclined tube body 20 . The inflow into the water supply tank 13 is blocked.

That is, the water heated by the heater 14 in the heating tank 15 has a low relative specific gravity, and the water not heated in the water supply tank 13 has a high relative specific gravity,

Even if water, which is heated in the heating tank 15 and has a low relative specific gravity, flows back into the second flow path pipe 22 having a second height h2, in the water supply tank 13, a first height h1 The inflow into the water supply tank 13 is blocked by the water having a high relative specific gravity flowing into the connection inclined pipe 23 inclined in the direction of the first flow pipe 21 and the second flow pipe 22 having a can become

Accordingly, the lime component generated inside the heating tank 15 is blocked from flowing into the water supply tank 13 from the backflow prevention of the heated water, and accordingly, the water level sensor 12a made of a capacitive type by the lime component. operation error will not occur.

That is, the lime component is fixed to the contact terminals a1 and a2 of the water level sensor 12a, so that the water level sensor 12a detects that there is no water even though there is water in the water supply tank 13 It can be prevented. there will be

On the other hand, as in FIGS. 7 and 8 , a water tank 10 divided into a water supply tank 13 and a heating tank 15 by a partition wall 11 is constituted, and the water supply tank 13 has a float On the other hand, in the state where the heater 14 is built in the heating tank 15, the solenoid valve 16a is opened and water is poured into the water supply tank 13 through the water supply pipe 16. water the

Then, the water supplied to the water supply tank 13 passes through the first flow path pipe 21, the connecting inclined pipe 23 and the second flow path pipe 22 of the inclined pipe body 20 having a first height h1. As it is supplied to the inside of the heating bath 13 through the heating bath 13, the water level in the heating bath 13 rises.

At this time, in a state in which the water level in the heating tank 13 rises, the water level in the water supply tank 13 also rises, and the rotating member b2 formed in the float type water level sensor 12b is raised by the water. When rotating around the hinge (h), the water level sensor (12b) generates a water detection signal according to the rise of the water level, and the solenoid valve (16a) is closed according to the water detection signal generated by the water level sensor (12b) An operation is made so that the water supply to the water supply tank 13 through the water supply pipe 16 is stopped.

Here, although it has been described to control the opening/closing operation of the solenoid valve 16a according to the water detection signal of the water level sensor 12b, the opening/closing operation of the solenoid valve 16a may be controlled by a control unit (not shown). Accordingly, the water detection signal of the water level sensor 12b may be configured to be output to the control unit.

And, in a state in which water is supplied from the water supply tank 13 to the heating tank 15 through the inclined tube body 20 as described above, when the heater 14 in the heating tank 15 performs a heating operation, the According to the heating operation of the heater 14 , water is evaporated to generate steam, and the steam is discharged to the outside through the steam outlet pipe 17 of the heating tank 15 .

At this time, when water is evaporated from the heating operation of the heater 14 to generate steam, the lime component contained in the water is generated in the heating tank 15 , and this lime component is passed through the inclined tube body 20 . The inflow into the water supply tank 13 is blocked.

That is, the water heated by the heater 14 in the heating tank 15 has a low relative specific gravity, and the water not heated in the water supply tank 13 has a high relative specific gravity,

Even if water, which is heated in the heating tank 15 and has a low relative specific gravity, flows back into the second flow path pipe 22 having a second height h2, in the water supply tank 13, a first height h1 The inflow into the water supply tank 13 is blocked by the water having a high relative specific gravity flowing into the connection inclined pipe 23 inclined in the direction of the first flow pipe 21 and the second flow pipe 22 having a can become

Accordingly, the lime component generated inside the heating tank 15 is blocked from flowing into the water supply tank 13 from the backflow prevention of the heated water, and accordingly, the water level sensor 12a made of a float type by the lime component. Operational errors will not occur.

That is, the lime component is fixed to the hinge (h) and the rotation of the rotating member (b2) included in the water level sensor (12b) is limited, and the water supply tank (13) detects that there is water even though there is no water. This will prevent errors.

Although the technical idea of the present invention for the steam generator has been described with the accompanying drawings, the best embodiment of the present invention has been exemplarily described, and the present invention is not limited thereto.

Therefore, the present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the present invention as claimed in the claims. It is, of course, possible that such modifications are intended to be within the scope of the appended claims.

10; water tank 11; septum
12a, 12b; water level sensor 13; water tank
14; heater 15; heating bath
16; water supply line 16a; solenoid valve
17; steam outlet pipe 20; inclined tube body
21; first flow pipe 22; 2nd flow pipe
23; connecting sergeant

Claims (3)

A water tank of the steam generator is divided into a water supply tank in which a water level sensor is installed and a heating tank in which a heater is installed through a partition wall, and the water supply tank and the heating tank are connected from the outside of the water tank by an inclined tube body,
The inclined pipe body may include a first flow path pipe connected to the water supply tank side; a second flow pipe connected to the heating tank side; and a connecting inclined pipe connecting the first flow pipe and the second flow pipe; including,
The first flow path pipe is configured to prevent water having a relatively low specific gravity, heated in the heating tank, and containing a lime component from flowing into the water supply tank through the second flow path pipe, the connecting inclined pipe, and the first flow path pipe. The first flow pipe and the second flow pipe are formed to have a height, and the second flow pipe is formed to have a second height lower than the first height, and the connection inclined pipe is inclined in the direction of the second flow pipe. 2 Steam generator, characterized in that for connecting the flow pipe. delete The steam generator according to claim 1, wherein the water level sensor is a capacitive type or float type water level sensor.

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