JPH08569Y2 - Steam generator - Google Patents

Description

[Detailed description of the device]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steam generator used for supplying steam to a steam sauna bath.

[Prior art]

A steam generator in which a heater 1 is provided in a lower portion of a tank 2 to generate steam by heating water stored in the tank 2 with the heater 1,
When steam is generated, the water level in the tank 2 will gradually drop. When the water level falls below that of the heater 1, the heater 1 is in an empty state and causes a malfunction. Therefore, as shown in FIG. 4, a water level sensor 8 is provided at the lowest water level in the tank 2, When the water level falls below the water level sensor 8, the power supply to the heater 1 is stopped. By thus stopping the power supply to the heater 1 by using the water level sensor 8, it is possible to prevent the heater 1 from being cooked empty, and at the same time, the tank 2
It is also possible to prevent the scale from precipitating by preventing the scale (scale) component in the residual water in the inside from being concentrated to a predetermined concentration or more. Then, after the energization of the heater 1 is stopped, water is supplied from the water supply pipe 17 into the tank 2 to fill it with water, and the heater 1 is energized again to generate steam.

[Problems to be solved by the device]

However, even if the water level is lowered as described above, even if the scale component in the residual water in the tank 2 is not concentrated by stopping the energization of the heater 1, the residual water in the tank 2 is not discharged into the tank 2. If water is repeatedly supplied to generate steam, scale components will be accumulated in the water in the tank 2 and the scale components will be concentrated. Eventually, scale will deposit and malfunctions such as drainage failure will occur. Cause of. Therefore, as a correct operation, when the water level is lowered and the power supply to the heater 1 is stopped, the residual water in the tank 2 is drained.
Although it is recommended to supply the tank 2 with full water after draining from the tank 12, this operation is not always protected, and the residual water in the tank 2 is not discharged due to an erroneous operation. Under the present circumstances, there is a possibility that the gas may be supplied to the inside of the No. 2 to deposit scale. The present invention has been made in view of the above points, and there is no fear that the scale will be concentrated even if an erroneous operation of supplying water into the tank without discharging residual water in the tank is performed.
In addition, it is an object of the present invention to provide a steam generator that can know the remaining steam generation time.

[Means for Solving the Problems]

The present invention relates to a steam generator including a tank 2 for storing water and a heater 1 built in the tank 2 to generate steam by heating water in the tank 2, and a temperature sensor provided in the tank 2. 3 and the time when the water temperature detected by the temperature sensor 3 is equal to or higher than a predetermined temperature at which steam is generated, and the time at which steam can be generated at the amount of water when the tank 2 is full , A heater stopping means for stopping energization of the heater 1 when this time calculated by the calculating means becomes zero, and a clearing of the integrated time when the residual water in the tank 2 is drained. And a resetting means for resetting.

[Action]

In the present invention, the temperature sensor 3 provided in the tank 2 detects the water temperature in the tank 2, and the time when the detected water temperature is equal to or higher than a predetermined temperature at which steam is generated is integrated as steam. By detecting the amount of water consumed and back-calculating the water level of the residual water in the tank 2 to stop energizing the heater 1, the heater 1 is cooked empty, or scale components are concentrated in the residual water of the tank 2. Can be prevented. If the residual water in the tank 2 is not drained, the accumulated time is cleared and is not reset. Therefore, even if the heater 1 is erroneously operated to supply water into the tank 2 without discharging the residual water in the tank 2, There is no fear that the scale will be concentrated without being energized. In addition, the remaining steam generation time can be known by displaying, as the remaining steam generation time, the time obtained by subtracting this integrated time from the time at which steam can be generated when the tank 2 is full.

【Example】

Hereinafter, the present invention will be described in detail with reference to embodiments. FIG. 1 shows an embodiment of the present invention, in which an electric heater 1 is provided in the lower end portion of a tank 2. Tank 2
One end of the steam supply pipe 9 is connected to the side wall of the upper end of the steam supply pipe 9, and the other end of the steam supply pipe 9 is connected to the steam nozzle 11 provided on the wall 10 of the steam sauna bath. Further, one end of a drain pipe 12 provided with an electromagnetic valve 13 in the middle is connected to the lower end of the tank 2, and the other end of the drain pipe 12 is connected to a drain port 14. A cistern 15 provided with a water tap with float 16 is arranged on the upper side of the tank 2, and one end of a water supply pipe 17 is connected to the lower part of the cistern 15 and the other end of the water supply pipe 17 is connected to the solenoid valve 13 more than the tank. It is connected to the drain pipe 12 at a position near the second side. In FIG. 1, reference numeral 18 denotes an overflow pipe, one end of which is opened in the upper end portion of the cistern 15, and the other end is connected to the drain pipe 12 at a position closer to the drain port 14 side than the solenoid valve 13. . A bypass pipe 19 is connected between the water supply pipe 17 and the overflow pipe 18 at the same height as the highest water level in the tank 2. The bypass pipe 19 is connected to the water supply pipe 17 at a position closer to the tank 2 than the solenoid valve 20 provided in the water supply pipe 17. Further, a temperature sensor 3 for measuring the water temperature in the tank 2 is provided in the lower portion of the tank 2. Then, in the steam generating device formed as described above, a fixed amount of water is always stored in the cistern 15 by the water tap with float 16, and the solenoid valve 13 opens the solenoid valve 20 in the closed state. As a result, the water in the cistern 15 can be supplied from the water supply pipe 17 to the inside of the tank 2 through the upper end portion of the drainage pipe 12, and the water level in the tank 2 reaches the height position of the bypass pipe 19 become. Water exceeding the full state enters the overflow pipe 18 through the bypass pipe 19 and is drained from the drain port 14 through the drain pipe 12. Then, the heater 1 is energized to heat the water in the tank 2 to generate steam, and the generated steam is supplied to the steam nozzle 11 of the steam sauna bath through the steam supply pipe 9 to generate the steam in the steam sauna bath. You can warm your body with steam and take a bath indoors. The water in the tank 2 can be discharged by operating the drain lever 49 to open the solenoid valve 13, causing the drain pipe 12 to flow from the drain port 14 to the drain trap 44, and then draining the drain pipe 45. Is done.
Since the water in the tank 2 is high temperature water, the solenoid valve 20 is also opened at the same time to send the water in the cistern 15 to the drain pipe 12,
The water in the tank 2 is mixed with the high temperature water in the tank 12 so that the water can be discharged with the water temperature lowered. If this mixing is insufficient, a solenoid valve 50 is installed between the water supply pipe 17 and the overflow pipe 18 to connect both pipes 17 and 18, and
It is preferable that the water inside the drain pipe 12 is also flowed through the overflow pipe 18 and mixed with the hot water from the inside of the tank 2. Here, the amount of water vaporized as steam is the lowest water level of the water stored in the tank 2 that does not expose the heater 1 from the amount of water filled in the tank 2 (the water level is indicated by HL in FIG. 1) ( The water amount is the water amount obtained by subtracting the water amount shown in Fig. 1 as LL. On the other hand, the temperature sensor 3 provided in the tank 2 always detects the water temperature in the tank 2, and if the water temperature is 90 ° C. or higher, it can be known that steam is generated. Then, when the water temperature is 90 ° C. or higher, the time during which the heater 1 is energized is measured by a timer, and when the timer measurement time is added up, the remaining time T at which steam can be generated is full in the tank 2. Time to generate steam with the amount of water at time T ₀
The time obtained by subtracting the integrated time T ₁ from the above, ie, T = T ₀
Calculated as -T ₁ . Therefore, the remaining time of steam generation can be calculated continuously instead of stepwise.
Further, when the accumulated time T ₁ reaches the time T ₀ at which steam can be generated with the amount of water when the tank 2 is full, it means that the water level in the tank 2 has dropped to the minimum water level LL. At this point, the energization of the heater 1 is automatically stopped. FIG. 2 is a block circuit diagram showing the structure of means for calculating and displaying the remaining time of steam generation and controlling the energization of the heater 1. The temperature sensor 3 provided in the lower portion of the tank 2 and the temperature sensor A steam generation determination unit 30 that outputs a steam generation signal when the water temperature detected in 3 becomes equal to or higher than the steam generation reference temperature (90 ° C),
A heater energization detection unit 31 that outputs a signal when the energization state to the heater 1 is detected, and an operation time integration unit 32 that accumulates and counts when both the energization detection signal to the heater 1 and the steam generation signal are obtained. , The operable time setting unit 33 that sets the steam generation time T ₀ when the tank 2 is full, and the integrated time T ₁ output from the operating time integration unit 32 are the time T output from the operable time setting unit 33. A subtraction processing unit 34 that calculates the remaining steam generation time T by subtracting from _0, a remaining time display unit 35 that displays the remaining steam generation time that is output from the subtraction processing unit 34, and a steam that is calculated by the calculation processing unit 34. It is composed of a heater control unit 37 that shuts off the power supply to the heater 1 when the remaining time T of occurrence is zero. Here, the operation time integration unit 32 is formed of a stopwatch circuit that performs a timekeeping operation when a steam generation signal is output,
This stopwatch circuit operates the drainage lever 49 to open the solenoid valve 13 of the drainage pipe 12, and when the residual water in the tank 2 is drained, a drainage completion signal output from the drainage completion detection unit 36 is used. The total time is cleared. Further, the remaining time display unit 35 for displaying the remaining steam generation time can be formed on the display plate provided inside or outside the steam sauna bath by a lamp method or a digital method. In the embodiment of FIG. 2 described above, the steam generation determination unit 30, the heater energization detection unit 31, the operation time integration unit
32, the operable time setting unit 33, and the subtraction processing unit 34 form a calculation means, and the discharge end detection unit 36
The reset means is formed by. FIG. 3 is a time chart of a specific example from the start of energization of the heater 1 to the drainage of residual water in the tank 2. When the energization of the heater 1 is started, the water temperature rises, but steam The water level does not fall because it has not yet occurred.
Then, when the water temperature exceeds 90 ° C, steam starts to be generated and the water level starts to drop. When it is detected that the water level has dropped to the lowest water level by integrating the time when the water temperature detected by the temperature sensor 3 is equal to or higher than the predetermined temperature for generating steam, the heater 1 is connected to the heater 1 as described above. Energization is stopped. Therefore, it is possible to prevent the water level in the tank 2 from being lowered too much and the heater 1 to be exposed above the water surface to be in an empty state, or the scale component in the residual water in the tank 2 to be excessively concentrated. Further, at this time, even if water is supplied into the tank 2 and the heater 1 is energized again, the integrated time is not cleared and reset,
The heater 1 cannot be energized. Therefore tank 2
Even if you make a mistake in supplying water without draining the residual water from
Since the heater 1 cannot be energized, there is no fear of accumulating scale in the water in the tank 2. Next, the solenoid valve 13 is opened to drain the residual water in the tank 2 from the drain pipe 12. Since the drainage requires about 3 minutes, the accumulated time is cleared and reset when the predetermined time required for the drainage has elapsed. Therefore, at this point, the heater 1 is reset to a state in which power can be supplied,
Steam can be generated again by supplying water to the tank 2 to fill the tank 2 with electricity and energizing the heater 1. In the above embodiment, the water supply pipe 17 is connected to the cistern 15 to supply the water stored in the cistern 15 to the tank 2. However, the water supply pipe 17 is connected to the water supply pipe 17 to supply water. You may do it.

[Effect of device]

As described above, in the present invention, the temperature sensor is provided in the tank, and the time when the water temperature detected by the temperature sensor is equal to or higher than the predetermined temperature at which steam is generated is integrated and when the tank is full of water. Since the calculation means for performing a calculation for subtracting this integrated time from the time at which steam can be generated with the amount of water and the heater stop means for stopping the energization of the heater when this time calculated by the calculation means becomes zero, It is possible to detect the amount of water consumed as steam by integrating the time when the water temperature detected by the temperature sensor is equal to or higher than the predetermined temperature for generating steam, and it is possible to calculate the residual water level in the tank backwards.
By stopping the energization of the heater at the time when it is detected that the water level has reached the minimum level, it is possible to prevent the heater from being boiled and the scale component in the residual water being concentrated. Since the reset means is provided for clearing and resetting the accumulated time when the residual water in the tank is drained, this accumulated time will not be cleared and reset unless the residual water in the tank is drained. Even if an erroneous operation of supplying water into the tank without discharging the residual water therein is prevented from energizing the heater and preventing the scale from being concentrated. In addition, by calculating and subtracting this cumulative time from the time when steam can be generated with the amount of water when the tank is full, that time can be known as the remaining steam generation time.

[Brief description of drawings]

FIG. 1 is a schematic diagram of an embodiment of the present invention, FIG. 2 is a block circuit diagram showing a constitution of means for displaying the remaining steam generation time and controlling energization to a heater, and FIG. 3 is the same as above. A time chart of water temperature and water level in the tank, and FIG. 4 is a schematic view of a conventional example. 1 is a heater, 2 is a tank, and 3 is a temperature sensor.

Continued Front Page (72) Inventor Tadashi Hirose 3-6-1, Shintaka, Yodogawa-ku, Osaka City, Meiji National Industrial Co., Ltd. (72) Noriaki Izumi 3-6-1, Shintaka, Yodogawa-ku, Osaka City, Osaka Prefecture Meiji National Industry Co., Ltd. (72) Inventor Satoshi Kawaguchi 3-6-1, Shintaka, Yodogawa-ku, Osaka City, Osaka Prefecture Meiji National Industry Co., Ltd. (56) References: 59-158948 (JP, U)

Claims (1)

[Scope of utility model registration request] 1. A steam generator comprising: a tank for storing water; and a heater built in the tank for generating steam by heating water in the tank, a temperature sensor provided in the tank, and a temperature sensor. A calculating means for adding up the time when the water temperature detected by is equal to or higher than a predetermined temperature for generating steam and subtracting this integrated time from the time when steam can be generated with the amount of water when the tank is full And a heater stop means for stopping energization of the heater when this time calculated by the calculation means becomes zero, and a reset means for clearing and resetting the integrated time when the residual water in the tank is drained. Steam generator.