JPH0743013A - Carbonated hot water supplying apparatus - Google Patents

Abstract

PURPOSE:To provide bubble separation means which is easy to be assembled into an instrument by providing means for restricting the flow velocity of water or hot water on the downstream side of a gas/liquid contact portion on a passage and hereby preventing bubbles in exhaust gas from being supplied to a portion to be supplied together with water or hot water. CONSTITUTION:Value control means 101 adjusts the valve travel of a butterfly valve V based upon detection information of a water level sensor S8 for detecting a water level in a bath tank B in a bathing hot water supply mode and a carbonated hot water supply mode. The valve travel of the butterfly valve V is set to be that of 30% when the water level in the bath tank B is 0. Thereafter, as the valve travel is increased in proportion to the water level to a predetermined water level, the valve travel is set to 100% one. As hot water supply operation by the bathing hot water mode and the carbonated hot water supply mode is completed, the valve control means 101 fully opens the butterfly valve V for a set time. Further, after the lapse of the set time, the valve control means 101 starts closing of the butterfly valve V, and simultaneously with sealing water being drained the butterfly valve V is fully closed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carbonated water heating apparatus in which a gas-liquid contact portion for contacting water or hot water with the exhaust gas of a hot water supply burner is provided on the way of supplying water or hot water to a supplied portion. Regarding

[0002]

2. Description of the Related Art Conventionally, in this type of carbonated water heater,
A bubble separating means for separating and extracting bubbles of exhaust gas mixed in water or hot water from the gas-liquid contact portion of the path for supplying water or hot water to the supplied portion was provided. (Japanese Patent Application No. 5-18, which is a prior application by the applicant.
474).

[0003]

However, according to the above-mentioned prior art, since the bubble separating means is relatively large, it is difficult to assemble it into a device and requires a lot of assemble space. However, there was an inconvenience that the production cost increased. An object of the present invention is to eliminate the above-mentioned conventional drawbacks.

[0004]

A first characteristic configuration of a carbonated water heater according to the present invention is a flow velocity limiting means for limiting the flow velocity of water or hot water in the path downstream of the gas-liquid contact portion. Is provided.

A second characteristic configuration of the carbonic acid water heating apparatus according to the present invention specifies a preferable specific configuration when the first characteristic configuration is carried out, in which the supplied portion is below the gas-liquid contact portion. The flow rate limiting means includes a flow rate adjusting valve that adjusts the flow rate of the path and a valve control means that controls the opening degree of the flow rate adjusting valve. However, it is configured such that the opening degree is adjusted based on the detection information of the water level detecting means for detecting the water level of the bathtub.

[0006]

According to the first characteristic configuration of the present invention, since the flow velocity limiting means for limiting the flow velocity of water or hot water is provided on the downstream side of the gas-liquid contact portion of the route, the flow velocity in the route can be reduced. It can be restricted so that it does not become faster than the set value, and it is possible to prevent the bubbles of the exhaust gas from being supplied to the supply target together with water or hot water by being swept away by the fast flow.

According to the second characteristic configuration, the flow velocity limiting means is composed of the flow rate adjusting valve, and the opening degree of the flow rate adjusting valve is adjusted based on the water level of the bathtub. By adjusting the opening degree of the valve in accordance with the above, the flow velocity in the path can be controlled to a constant speed.

That is, since the path is open to the atmosphere by providing the gas-liquid contact portion, hot water is supplied to the bathtub by a so-called “drop” due to a difference between the gas-liquid contact portion and the water surface of the bathtub. Is configured to be. Therefore, the flow velocity at the time of dropping in the path is
When the water level in the bathtub is low, it tends to be fast, and when it is high, it tends to be slow.However, if the opening of the flow control valve is adjusted to open small when the water level in the bathtub is low and open wide when it is high, the flow velocity in the path Can be controlled at a constant speed.

[0009]

According to the first characteristic configuration of the present invention, the provision of the flow velocity limiting means can prevent the bubbles of the exhaust gas from being supplied to the supply target portion. By comparison, it is possible to provide a carbonated water heating apparatus that is easy to install in a device, does not consume an installation space, and has a reduced production cost.

According to the second characteristic configuration, the flow velocity in the route can be controlled to a constant velocity by adjusting the opening degree of the valve according to the water level in the bathtub. It is possible to provide a carbonated water heating apparatus in which the time required for hot water supply is shortened as much as possible without unnecessarily slowing down the flow velocity while limiting to the following.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. In FIG. 1, a carbonated water heating apparatus is provided with a gas-liquid contact portion G for contacting water or hot water with the exhaust gas of the hot water supply burner 2 in the middle of a path for supplying water or hot water to a bath B as a supply target portion. It is shown. The carbonated hot water supply device includes a hot water supply unit A that heats tap water supplied through the water supply passage W1 to supply hot water to the bathtub B and the hot water tap K, and a reheating unit C that reheats bathtub water in the bathtub B. It is composed of a gas-liquid contact portion G for bringing water or hot water into contact with the exhaust gas of the hot water supply burner 2, and a control portion H for controlling the operation of the carbonated water heating apparatus.

In the hot water supply unit A, there are provided a hot water supply heat exchanger 1 for supplying tap water through a water supply passage W1, a hot water supply burner 2 for heating the hot water supply heat exchanger 1, and a combustion air for the hot water supply burner 2. A blower fan 3 for blowing air is provided. The hot water supply burner 2 is provided with a fuel control valve 4 for adjusting the amount of fuel supplied to the hot water supply burner 2 and a fuel interruption valve 5. Further, the rotation speed of the blower fan 3 is controlled to a value determined according to the fuel supply amount so that the amount of blown air is such that the combustion state of the hot water supply burner 2 is optimized.

The reheating section C includes a reheating heat exchanger 6 provided in a circulation path W5 for circulating the bath water of the bathtub B, a reheating burner 7 for heating the reheating heat exchanger 6, and a reheating unit. It is composed of a blower fan 8 that blows the combustion air of the combustion burner 7.
A circulation pump 9 is provided in the circulation path W5. The additional heating burner 7 is provided with a fuel control valve 10 for adjusting the amount of fuel supplied to the additional heating burner 7 and a fuel interrupt valve 11. The blower fan 8, like the blower fan 3, is controlled according to the additional heating burner 7.

The gas-liquid contact portion G is the exhaust duct 1 of the hot water supply portion A.
2 are connected so that the exhaust gas from the hot water supply burner 2 passes through, and the hot water supply passage W2 that guides the hot water from the hot water supply heat exchanger 1 to the gas-liquid contact portion G and the water from the water supply passage W1 are vaporized. The water supply path W3 that leads to the liquid contact portion G and the hot water supply path W4 that guides hot water from the gas-liquid contact portion G to the bathtub B are connected to relay the path for supplying hot water to the bathtub B. It is configured.

A water pool F for sealing the water path is provided below the gas-liquid contact portion G in this embodiment. The hot water supply passage W2 and the hot water supply passage W3 are connected so as to be located on the upstream side of the water pool portion F in the above route, and the water pool portion F is provided at the hot water supply passage W2 or a route portion from the hot water supply passage W2 to the hot water supply passage W4. It is configured to intervene.

In the carbonated water heater, first, a water supply passage W1 and
A heat exchanger 1 for hot water supply, a hot water supply passage W2, a water pool F,
The hot water supply passage W4 constitutes a passage for supplying hot water boiled by the hot water supply burner 2 to the bathtub B as appropriate for hot water supply.

The water supply passage W1 is provided with a thermistor S1 for detecting the water supply temperature Ti in the water supply passage W1 and a water amount sensor S2 for detecting the water supply amount Q from the water supply passage W1. The hot water supply passage W2 is provided with an intermittent valve 13.
The supply of hot water from the hot water supply heat exchanger 1 to the bathtub B is controlled. In the hot water supply passage W4, the hot water supply passage W4
And a butterfly valve V as a flow velocity limiting means for limiting the flow velocity of water or hot water in
A thermistor S3 for detecting x is provided.

The hot water supply passage W2 has a branching hot water supply passage W2.
6 is provided so that the hot water boiled by the hot water supply burner 2 can be appropriately supplied to the hot water tap K to perform general hot water supply. The hot water supply passage W6 is provided with a water amount sensor S4 for detecting opening of the hot water supply tap K.

The carbonated water heater has a water supply passage W1 and
Carbon dioxide contained in the exhaust gas of the hot water supply burner 2 is dissolved by passing through the gas / liquid contact portion G by the water supply passage W3, the gas-liquid contact portion G, the water pool portion F, and the hot water supply passage W4, and The hot water heated by the high-temperature exhaust gas is appropriately supplied to the bath B to provide carbonated hot water.

An on / off valve 14 is provided in the water supply passage W3 so that the water supply for carbon dioxide hot water supply to the gas-liquid contact portion G is controlled. When carbonated hot water is supplied, hot water is also supplied from the above-described path for hot water supply, and the hot water in both paths is mixed below the gas-liquid contact portion G before being added to the bathtub B. It is configured to be supplied by.

The bath B is arranged below the gas-liquid contact portion G. Further, the bathtub B is provided with a water level sensor S8 as a water level detecting means for detecting the water level L of the bathtub B by the water pressure.

The control unit H is mainly composed of a microcomputer, and is connected with the thermistors S1 and S3, water amount sensors S2 and S4, and a water level sensor S8.
While the detection information of these sensors is input, the fuel control valves 4 and 10, the fuel interrupt valves 5 and 11, the blower fans 3 and 8, the circulation pump 9, the interrupt valves 13 and 14, the butterfly valve V, and the controller 15 are connected. It is configured so that various operations of the carbonated water heater can be controlled by software that is connected and built in.

The controller 15 includes a hot water supply switch 15a, a carbonated water supply switch 15b, and a target hot water supply temperature T.
target hot water supply temperature setting switch 15c for setting s, and
An additional heating hot water switch 15d and the like are provided.

FIG. 2 shows the gas-liquid contact portion G in this embodiment.
It is shown. The gas-liquid contact portion G is provided with a plurality of jet nozzles 16 for jetting water supplied from the water supply passage W3 and a filling layer 17 in which a stainless wire is braided in a three-dimensional lattice shape in a metal casing. Below the packed bed 17,
The exhaust duct 12 of the hot water supply unit A is connected, and an exhaust port 18 is provided in the upper part of the casing.

The hot exhaust gas from the hot water supply burner 2 is introduced from the exhaust duct 12 into the casing of the gas-liquid contact portion G. The exhaust gas introduced into the casing rises toward the exhaust port 18. At this time, the filling layer 17 is heated to a high temperature through the filling layer 17 and comes into contact with water ejected from the ejection nozzle 16. Therefore, the exhaust gas of the hot water supply burner 2 dissolves the carbon dioxide in the exhaust gas into the water from the water supply passage W3, and the heat exchange with the water recovers the exhaust heat contained in the exhaust gas. Is configured to be.

A temperature sensor S5 for detecting the temperature of the gas-liquid contact portion G is provided near the filling layer 17 in the casing. The temperature sensor S5 is also connected to the control unit H.

At the bottom of the casing, the water pool F
Is provided. The water pool F is connected to the hot water supply passage W4 so that the water ejected from the ejection nozzle 16 and the hot water supplied from the hot water supply passage W2 are mixed to collect water. The outlet 19 to W4
It is provided at a position higher than the bottom of the casing, and the water or hot water accumulated in the lower part of the casing and the sealing plate 20 are configured to seal the path from the gas-liquid contact portion G to the bath B with water.

Thus, the water jetted from the jet nozzle 16 pours vigorously toward the water pool F while coming into contact with the exhaust gas of the hot water supply burner 2, so that in the water pool F, as shown in FIG. A large amount of air bubbles are mixed by the exhaust.

The water pool F is provided with a water level sensor S6 and a water level sensor S7 for detecting the water level of the sealed water, and an overflow 21. Water level sensor S6
Is provided at a height where the water outlet 19 is provided. The water level sensor S7 is provided at a position slightly higher than the lower end of the water sealing plate 20. The water level sensor S6 and the water level sensor S7 are also connected to the control unit H.

At the lower part of the water pool F, sealing water is supplied to the hot water supply passage W.
4, the pores 22 for gradually draining water are provided in the hot water supply passage W4.

Butterfly valve V provided in hot water supply passage W4
Is configured to be opened and closed by the drive motor 23, and is configured as a flow rate adjusting valve that adjusts the flow rate of the hot water supply passage W4. The drive motor 23 is connected to the control unit H and controls the opening of the butterfly valve V.
01 is configured.

Further, the butterfly valve V can completely close the hot water supply passage W4 by fully closing it.
It is configured such that exhaust gas and the like can be prevented from flowing into the bath B even when the water pool F is not sealed.

The control unit H is configured to execute the following four kinds of hot water supply modes. The first hot water supply mode is a hot water supply mode in which only hot water from the hot water supply heat exchanger 1 is supplied to the bathtub B. The second hot water supply mode is a carbonated hot water supply mode in which hot water from the hot water heat exchanger 1 and hot water that has passed through the gas-liquid contact portion G are mixed and supplied to the bathtub B. The third hot water supply mode is a general hot water supply mode in which hot water from the hot water supply heat exchanger 1 is supplied only to the hot water tap K. The fourth hot water supply mode is an additional hot water supply mode by the additional heating unit C.

In this embodiment, no hot water supply mode is provided in which hot water is supplied to the bathtub B and hot water to the hot water tap K at the same time, and the hot water supply mode or the carbonated hot water supply mode is executed. When the hot water supply tap K is opened, the hot water supply mode or the carbonated water supply mode is stopped and the general hot water supply mode is executed.

The controller 15 is used for the hot water supply mode.
This is performed by operating the hot water supply switch 15a. When the hot water supply switch 15a is operated, the blower fan 3
Is driven, the intermittent valve 13 is opened, the hot water supply burner 2 is ignited, the thermistors S1 and S3 and the water amount sensor S
Based on the detection result of No. 2, the fuel control valve 4 and the fuel interrupt valve 5 are set so that the hot water supply temperature Tx detected by the thermistor S3 approaches the target hot water supply temperature Ts set by the target hot water supply temperature setting switch 15c. The blower fan 3 is controlled and the rotation speed of the blower fan 3 is controlled accordingly.

In the carbonated water heating mode, the carbonated water heating switch 15 is used.
It is executed by the operation of b. Carbonated hot water switch 15b
When the is operated, first, the temperature of the gas-liquid contact portion G is checked by the temperature sensor S5, and if it is overheated to a predetermined temperature or higher, the blower fan 3 is driven to cool the gas-liquid contact portion G. Is done. When water is suddenly ejected from the ejection nozzle 16 in a state where the gas-liquid contact portion G is overheated to a predetermined temperature or more, an abnormal sound such as a shatter is generated, the water is violently evaporated, and a large amount of water is exhausted from the exhaust port 18 and the like. This is because water vapor is discharged, which is not preferable for using the carbonated water heater. If the gas-liquid contact portion G is below a predetermined temperature, the intermittent valves 13 and 14 are opened, the hot water supply burner 2 is ignited, and based on the detection results of the thermistors S1 and S3 and the water amount sensor S2, the thermistor S3. The fuel control valve 4 and the fuel interrupt valve 5 are controlled so that the detected hot water supply temperature Tx approaches the target hot water supply temperature Ts set by the target hot water supply temperature setting switch 15c, and the rotational speed of the blower fan 3 follows the control. Is controlled.

The general hot water supply mode is executed as the hot water supply tap K is opened. When the hot water tap K is opened, the intermittent valve 13 and the intermittent valve 14 are closed, and the temperature of the hot water supplied to the hot water tap K is the predetermined hot water temperature based on the detection results of the thermistor S1 and the water amount sensor S2. To be
The fuel control valve 4 and the fuel interrupt valve 5 are controlled, and the rotation speed of the blower fan 3 is controlled following the control.

In the additional heating hot water supply mode, the additional heating hot water switch 15 is used.
It is executed along with the operation of d. Additional heating hot water switch 15d
When is operated, the circulation pump 9 is operated, the blower fan 8 is driven, the additional heating burner 7 is ignited, and additional heating hot water is supplied. The combustion amount of the additional burning burner 7 is controlled to a constant strength with a relatively high thermal power.

The valve control means 101 uses the butterfly valve V based on the detection information of the water level sensor S8 for detecting the water level L of the bathtub B in the hot water supply mode and the carbonated water supply mode.
Is configured to be adjusted according to the relationship shown in FIG. FIG. 3 shows the relationship between the water level L of the bathtub B and the opening degree v (in%) of the butterfly valve V. The opening degree v of the butterfly valve V is set to 30% when the hot water supply is started, that is, when the water level L of the bathtub B is zero.
After that, as the water level L reaches the water level L ₁ , the opening v is increased in proportion to the water level L, and as the water level L reaches the water level L ₂ , the opening is set to 100%.

When the hot water supply operation in the hot water supply mode and the carbonated water supply mode is completed, the valve control means 101 fully opens the butterfly valve V for the set time. This set time is
It is set in consideration of the time taken for the sealing water in the water pool F to be drained by the pores 22. Then, as the set time elapses, the valve control means 101 starts to close the butterfly valve V, and when the sealing water is completely drained, the butterfly valve V is completely closed. .

[Other Embodiment] The valve control means 10 shown in FIG.
The control form 1 is merely an example, and can be changed as appropriate.

The flow velocity limiting means is not limited to the butterfly valve V and the valve control means 101, but can be changed appropriately. For example, the hot water supply pump is configured to supply hot water to the bathtub B, and by adjusting the pumping capacity of the hot water supply pump,
It may be configured to limit the flow velocity in the hot water supply path.

It should be noted that reference numerals are given in the claims for convenience of comparison with the drawings, but the present invention is not limited to the configurations of the accompanying drawings by the entry.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an overall configuration of a carbonated water heater.

FIG. 2 is a sectional view showing a structure of a gas-liquid contact portion and a butterfly valve.

FIG. 3 is a graph showing a control mode of valve control means.

[Explanation of symbols]

 B Bathtub (supplied part) G Gas-liquid contact part L Water level S8 Water level detection means V Flow rate adjusting valve (flow rate limiting means) 2 Hot water burner 101 Valve control means (flow rate limiting means)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shigenobu Okuda 4-1-2, Hirano-cho, Chuo-ku, Osaka City, Osaka Prefecture Osaka Gas Co., Ltd. No.52 Harman Co., Ltd.

Claims (2)

[Claims] 1. A gas-liquid contact portion (G) for contacting water or hot water with the exhaust gas of the hot water supply burner (2) is provided in the middle of a path for supplying water or hot water to the supplied portion (B). A carbonated water heater, wherein a flow velocity limiting means (V, 101) for limiting the flow velocity of water or hot water in the route is provided on the downstream side of the gas-liquid contact portion (G) in the route. . 2. The supplied part (B) is composed of a bath (B) arranged below the gas-liquid contact part (G), and the flow velocity limiting means (V, 101) is provided in the path. The flow rate adjusting valve (V) for adjusting the flow rate and the valve control means (101) for controlling the opening of the flow rate adjusting valve (V) are provided, and the valve control means (101) is used for the bathtub (B). 2. The carbonated water heater according to claim 1, wherein the opening degree is adjusted based on the detection information of the water level detecting means (S8) for detecting the water level (L).