JPH0722571Y2 - Steam generator - Google Patents

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a steam generator used for steam saunas, steam heating, etc., and more specifically, abnormality detection for avoiding problems due to scale clogging. Regarding those with functions.

<Prior Art> Generally, it is well known that in a steam generator, scale components in raw water are condensed and deposited as they evaporate. It causes valve failure.

On the other hand, the applicant has provided a scale collection tank from the evaporation tank to the drain valve so that the scale in the evaporation tank is stored in the scale collection tank at the time of drainage so that the drain valve is less likely to malfunction. (See Japanese Utility Model Application No. 1-36250) (Japanese Utility Model Application No. 2-128038).

This device will be described with reference to FIG.

In the figure, 1 is a water supply means comprising a water supply source valve 1a, a water supply tank 1b and a water supply pump 1c, 2 is an evaporation tank which is supplied by the water supply means 1 and is heated by a heating means 3 such as a burner, and 4 is an evaporation tank. The scale collection tank 5 connected to the opening 2a provided at the bottom of the 2 and arranged below the opening 2a is a drain valve interposed in the middle of a drain pipe 6 connected to the upper portion of the scale collection tank 4. Further, 7 is a water level detection chamber that communicates with the evaporation tank 2, and 8A to 8C are first to third such as float switches that are provided at three positions in the water level detection chamber 7 in the vertical direction and that detect the water level of the evaporation tank 2. The water level detection switch 9 is a controller for controlling the operations of the water supply means 1, the heating means 3 and the drain valve 5 based on the ON / OFF states of the first to third water level detection switches 8A to 8C.

Next, the operation will be described.

First, when the steam generation operation is started, the water supply means 1 supplies water to the evaporation tank 2. As the water level in the evaporation tank 2 rises, the first and second water level detection switches 8A and 8B are sequentially turned on. Therefore, the water level reaches the lower water level L ₁ ,
When the water level detection switch 8A is turned on, heating by the heating means 3 is started. After that, when the water level reaches the middle water level L ₂ and the second water level detection switch 8B is turned on, the water supply by the water supply means 1 is stopped. The steam generated in the evaporation tank 2 by heating is supplied to a steam chamber (not shown) as shown by an arrow. Due to this heating evaporation, the water level in the evaporation tank 2 drops below the lower water level L ₁ and the first water level detection switch 8A
When is turned off, water is supplied by the water supply means 1. When the water level is raised to the middle water level L ₂ by the water supply and the second water level detection switch 8B is turned on, the water supply is stopped. That is, steam is generated between the middle water level L ₂ and the lower water level L ₁ , and this operation is repeated during operation.

When the steam generating operation is stopped, the heating by the heating means 2 is stopped, and the water supply means 1 causes the evaporation tank 2 to operate.
Is supplied to. This water supply raises the water level to the upper water level L ₃
When the third water level detecting switch 8C is turned on to turn on, the water supply is stopped and the drain valve 5 is opened to drain the water in the evaporation tank 2. By this drainage, evaporation tank 2
The water generated in the evaporation tank 2 is discharged through the drain valve 5 while the scale generated in 1 is stored in the scale collection tank 4.
5 (a) to 5 (c) show on / off operations of the water level detection switches 8A to 8C during normal wastewater treatment. When the operation is stopped in this way, water is supplied to a position above the water level during the steam generating operation, so that the scale generated by the steam generating operation and attached to the wall surface of the evaporation tank 2 is washed. Has become.

<Problems to be Solved by the Invention> Incidentally, even in the above-mentioned conventional example, there is room for improvement in the following points.

That is, when the scale storage amount in the scale collection tank 4 becomes full, the scale in the scale collection tank 4 is filled with the evaporation tank 2
To the drainage valve 5 side when the scale 10 in the scale collection tank 4 overflows to the drainage valve 5 side.
There is a risk that the unit will break down, making it impossible to open and close.

If the pipe 10 is clogged or the drain valve 5 fails as described above, the cleaning process cannot be executed due to the stop of the steam generation operation. In other words, water supply is performed by stopping the steam generation operation, the water level rises to the upper water level L ₃ , the third water level detection switch 8C is turned on, and the water supply is stopped and drainage is started, but it evaporates forever. The water in the tank 2 will not be drained. At this time, the water level detection switches 8B and 8C are not turned off as shown in FIGS. 5 (e) and 5 (f).

When the next steam generation operation is started in such a state, the water in the evaporation tank 2 overflows due to the water supply and flows out into the steam chamber, and heating is not performed forever and steam is not generated. Cause a situation.

That is, even if the drainage failure caused by the scale clogging as described above occurs, the user cannot easily recognize the occurrence of the abnormality. Normally, when the next steam generation operation is started, the above-mentioned adverse effects occur, so that the user can finally recognize that an abnormality has occurred at that time.

The present invention was devised in view of such circumstances, and makes it possible to reliably perform the cleaning of the evaporation tank as in the conventional case, and to prompt the user to immediately recognize the drainage defect due to the clogging of the scale so that an early countermeasure can be taken. The purpose is to

<Means for Solving the Problems> In the conventional steam generator, as described above, by stopping the steam generation operation, the evaporating tank wall surface is washed by supplying water up to a predetermined upper limit water level in the evaporating tank and completely draining it. I do.
That is, when the water level detection switch at the uppermost position is turned on by the water supply to the evaporation tank, the water supply is stopped and the water is drained. When the drainage can be normally performed, the water level is lowered by the drainage, and each water level detection switch under the uppermost water level detection switch is sequentially turned off after a predetermined time has elapsed since the uppermost water level detection switch was turned on. However, if the water cannot be drained, the water level detection switch will not turn off forever. Therefore, in a normal case, the time from the start of drainage until the predetermined water level detection switch is turned off (corresponding to T in FIG. 5) is almost fixed. Therefore, by managing this time, scale clogging occurs. The inventors of the present invention thought that they could recognize.

Therefore, the present invention is directed to an evaporation tank which is supplied with water from a water supply means and is heated by a heating means, a scale collection tank which is connected to an opening provided at the bottom of the evaporation tank and which is arranged below the evaporation collection tank, and an upper portion of the scale collection tank. A drainage valve interposed in the middle of a drainage pipe connected to the water vaporizer, and at least three water level detection switches that are provided at several positions in the vertical direction in the water level detection chamber communicating with the evaporation tank and detect the water level of the evaporation tank, A steam generator having a controller that controls the operations of the water supply means, the heating means, and the drain valve based on the on / off states of these switch detection switches has the following configuration.

The steam generator of the present invention includes an alarm means for notifying a user of scale clogging and a water level detection switch when the steam generation operation is stopped.
The elapsed time from when the highest water level detection switch is turned on to when the lower water level detection switch is turned off is measured, and the measured value is a preset threshold value. And a timing means for giving a time-up signal to the controller when the time exceeds, and the controller detects a pair of upper and lower water levels of the water level detection switch except the highest water level detection switch during the steam generation operation. While controlling the water supply by the water supply means while the switch is turned on and off, the heating means is stopped in accordance with the stoppage of the steam generation operation, and the water supply means starts the water supply to the evaporation tank to obtain the highest water level. In response to the ON operation of the detection switch, the water supply is stopped and the drain valve is opened, and when a time-up signal is given from the timing means, In response to this, a sequence for operating the alarm means is executed.

<Operation> Water is supplied until the highest water level detection switch is turned on in response to the stoppage of the steam generation operation, so the water level is higher than the maximum water level during the steam generation operation. The scale is surely washed. In addition, the time measuring means measures the time required from the ON operation of the highest water level detecting switch indicating the start of drainage to the turning off of the water level detecting switch located below it, and this normal time is measured by the time measuring means. Set as a threshold value. Therefore,
When it becomes impossible to drain water due to clogging of the scale, the water level does not drop, so the predetermined water level detection switch does not turn off. In this case, since the time from the start of drainage until the predetermined water level detection switch is turned off exceeds the threshold value, the timing means gives a time-up signal to the controller to operate the alarm means. In other words, the operation of the alarm means allows the user to recognize the occurrence of scale clogging, and thus the scale clogging can be dealt with early.

<Embodiment> An embodiment of the present invention will be described below in detail with reference to the drawings.

1 to 3 show an embodiment of the present invention.
In the drawing, the same parts and portions as those shown in FIG. 4 of the conventional example are designated by the same reference numerals, and detailed description thereof will be omitted.

In this embodiment, the configuration different from the conventional example is that the controller 9 has a timer 11 built therein as a time measuring means, and
The alarm means 12 such as an alarm buzzer operated by the controller 9 is provided.

Specifically, the timer 11 has a second water level detection switch 8B at the middle position after the third water level detection switch 8C at the uppermost position is turned on.
A time-up signal is given to the controller 9 when the elapsed time until the switch turns off exceeds a predetermined threshold value set in advance. The controller 9 has a function of operating the alarm means 21 in response to the time-up signal.

The above-mentioned threshold value is set based on the elapsed time in the normal state.

Next, the operation will be described with reference to FIG.

When the steam generating operation is stopped, water supply is started in step S1 and it is determined in step S2 whether or not the third water level detection switch 8C is turned on. That is, when the water level of the evaporation tank 2 rises due to the water supply, the water level reaches the upper water level L ₃ and the third water level detection switch 8C is turned on, it is determined to be YES in step S2, and the water supply is stopped and stopped in step S3. Drainage is started, and the timer 11 is set in step S4.

Then, in step S5, it is determined whether or not the second water level detection switch 8B is turned off. The drainage causes the water level in the evaporation tank 2 to drop below the middle water level L ₂ and the second water level detection switch 8B.
Is turned off, YES is determined in step S5, and step S5
After resetting the timer 11 at 6, it ends without any abnormality. On the other hand, if the drainage cannot be performed due to the clogging of the scale, the water level does not drop and the second water level detection switch 8B remains off.
In step S7, it is determined whether or not the timer 11 has timed out. If the time is not up, in step S7
If NO is determined and the process returns to step S5, if time is up, YES is determined in step S7 and the process proceeds to step S8.
In step S8, the alarm means 12 is operated and the process ends. At the same time as the operation of the alarm means 12, the type of abnormality may be displayed or all the operations may be stopped.

As explained above, if scale clogging occurs during the drainage phase due to the operation stop, the user can be immediately notified of the abnormality indicating that drainage is not possible, and the abnormality can be dealt with immediately. You can do it. Therefore,
In the next steam generation operation, it is possible to prevent problems that have occurred in the past.

By the way, in this embodiment, as shown in FIG. 3, a ball 13 which is lighter than the specific gravity of water is housed in the evaporation tank 2 so as to almost completely fill the water surface in the evaporation tank 2 and The slightly heavy balls 14 are housed so as to be densely distributed in the water in the evaporation tank 2. These balls 13 and 14 operate as follows.

That is, first, the group of balls 13 floating on the water surface moves according to the convection of water due to heating, and subdivides the bubbles (steam) generated on the water surface to separate the gas component and the water. In addition, the balls 14 floating in the water move in response to the convection of the water due to the heating as described above to subdivide the bubbles generated in the water and also to remove the scale attached to the inner wall surface of the evaporation tank 2 from the wall surface. Let go. If such balls 13 and 14 are used, the evaporation tank 2
In, the internal space required for air-water separation can be reduced. That is, in the past, the internal space of the evaporation tank 2 was made as large as possible in order to promote the separation of the gas component and the water, which hindered the downsizing of the device.
This problem can be solved by using 13,14.

<Effects of the Invention> As described above, according to the present invention, water is supplied to a level higher than the maximum water level during the steam generation operation according to the stoppage of the steam generation operation. It is surely washed. Further, when the drainage becomes impossible due to the clogging of the scale, the alarm means is activated to notify the user of the occurrence of the abnormality at the early stage of the abnormality occurrence, so that the abnormality can be dealt with immediately after the occurrence of the abnormality. Since early detection and early countermeasures can be realized in this way, it is possible to prevent the occurrence of secondary adverse effects as described in the conventional example.

[Brief description of drawings]

1 to 3 relate to an embodiment of the present invention, FIG. 1 is a sectional view showing a schematic configuration of a steam generator, FIG. 2 is a flow chart showing a process for performing abnormality detection, and FIG. FIG. 3 is a cross-sectional view showing the inside of the evaporation tank. Further, FIGS. 4 and 5 relate to a conventional example, FIG. 4 is a cross-sectional view showing a schematic configuration of a steam generator, and FIG. 5 is a time chart showing the operation of a water level detection switch in a normal state and an abnormal state. is there. 1 ... water supply means, 2 ... evaporation tank, 3 ... heating means, 4 ...
... scale collection tank, 5 ... drain valve, 8A-8C ... water level detection switch, 9 ... controller, 11 ... timer, 12
…… Alarm means.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-59-32701 (JP, A) JP-A-63-80107 (JP, A) Practical application Sho-54-124336 (JP, U)

Claims (1)

[Scope of utility model registration request] 1. An evaporation tank which is supplied with water from a water supply means and is heated by a heating means, a scale collection tank which is connected to an opening provided at the bottom of the evaporation tank and which is arranged below the opening, and the scale collection tank. A drainage valve interposed in the middle of a drainage pipe connected to the upper part, and at least three water level detection switches provided at several positions in the vertical direction in the water level detection chamber communicating with the evaporation tank and detecting the water level of the evaporation tank. In a steam generator equipped with a controller that controls the operations of the water supply means, the heating means, and the drain valve based on the on / off states of these switch detection switches, an alarm means that notifies the user of scale clogging and a steam generation operation When stopped, of the water level detection switch,
The elapsed time from when the highest water level detection switch is turned on to when the lower water level detection switch is turned off is measured, and the measured value is a preset threshold value. And a timing means for giving a time-up signal to the controller when the time exceeds, and the controller detects a pair of upper and lower water levels of the water level detection switch except the highest water level detection switch during the steam generation operation. While controlling the water supply by the water supply means while the switch is turned on and off, the heating means is stopped in accordance with the stoppage of the steam generation operation, and the water supply means starts the water supply to the evaporation tank to obtain the highest water level. In response to the ON operation of the detection switch, the water supply is stopped and the drain valve is opened, and when a time-up signal is given from the timing means, In response to this, a sequence for operating the alarm means is executed, wherein the steam generator.