JPH046853B2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention makes it possible to save bath water by recycling the hot water in the bathtub, and to reduce the amount of hot water supplied indoors from the bathtub and hot water tank for drinking and cooking. The present invention relates to a hot water circulation heating device that can heat hot water for personal use or bathing with high efficiency and save thermal energy.

[Conventional technology]

Conventionally, when reusing hot water in a bathtub, impurities such as human hair and dirt in the bathtub water are filtered out and removed, and it is not possible to reuse it in a completely clean state. , was reused several times and then discarded. or,
Heating of bathtub water and drinking water supplied indoors was generally performed using separate heaters.

[Problem to be solved by the invention]

Therefore, in the conventional circulating use of bathtub water, only filtration is performed, which makes it impossible to sterilize the hot water, remove fat dispersed in the hot water, or remove odors.
It was becoming bad for my health. Furthermore, because the number of times the water can be recycled is limited, it has not resulted in fundamental water conservation. Furthermore, even when heating bathtub water or heating hot water, thermal energy cannot be saved, making it extremely uneconomical.

The present invention has been made in consideration of the above-mentioned circumstances, and provides a hot water circulation heating device that is capable of increasing the number of times bath hot water is circulated and used, thereby improving the water saving rate and saving thermal energy. be.

[Means for solving problems]

The present invention sterilizes and filters bathtub water to enable long-term circulation use, and also uses a heat pump to heat the bathtub water and hot water for hot water supply, and uses high-temperature refrigerant gas from the heat pump to supply hot water. This makes it possible to save thermal energy by circulating the heating of the hot water in the tank to the heating for the bathtub.

That is, the hot water circulation heating device according to the present invention,
a circulation tank that is connected to the bathtub by a pipe and is equipped with a filtration device, a pump, and an activation tank and that circulates bathwater between the bathtub and the bathtub; a temperature sensor that is installed in the bathtub; a sterilization means for supplying ozone air to sterilize the bath; a heating coil for heating the bath water by heat exchange; a hot water tank in which the heating coil is disposed; and a heat source for the refrigerant pipe. a heat pump equipped with a fan that blows air, and a compressor that compresses the refrigerant that has obtained heat into high-temperature gas; a refrigerant path that connects the heating coil, the heating coil, and the heat pump so that refrigerant gas circulates; A switching means is disposed in the refrigerant path and switches the refrigerant gas from the heat pump between the heating coil and the heating coil, and the temperature of the bath water is set, and the temperature is input from the temperature sensor, and the temperature is lower than the set temperature. It is characterized by comprising a control device that operates the switching means so that if the temperature is high, the refrigerant flows to the heating coil, and if the temperature is low, the refrigerant flows to the heating coil.

〔Example〕

Hereinafter, embodiments illustrating the present invention will be specifically described.

FIG. 1 is a piping system diagram of an embodiment of the hot water circulation heating device according to the present invention. This circulation heating device is
It is equipped with a circulation tank 2 that performs filtration while circulating the hot water in the bathtub 1, a heat pump 3 that compresses and heats refrigerant gas using outside air as a heat source, and a hot water tank 4 that stores hot water to be supplied indoors.

The circulation tank 2 has a filter 21 and a pump 2 inside.
2 are provided, and these are connected in series by a conduit. The bathtub 1 is an outgoing pipe 23.
and a return pipe 24, and the pump 2
2, the hot water in the bathtub 1 is guided into the filtration device 21 and filtered, and impurities such as human hair and dirt are removed. It's starting to gush inside. or,
An activation tank 25 filled with activated stones such as maifan stone and sulfur stone is connected between the filtration tank 21 and the pump 22. This activation tank 25 ion-exchanges the bath water that has passed through the filtration tank 21 to return it to its original water quality, and also elutes active ingredients such as iron, magnesium, calcium, and sodium contained in the activated stones into the bath water. It has the effect of increasing the bathing effect. A sterilizing means 5 is provided at a position adjacent to such a circulation tank 2. The sterilizing means 5 is provided with an ozone generator 51 therein, and an air pipe 52 is led out from the ozone generator 51, and this air pipe 52 is connected to the vicinity of the outlet of the outgoing pipe 23. Therefore, ozone from the ozone generator 51 is supplied from the outgoing pipe 23 into the bathtub water and is ejected into the bathtub 1 together with the jet water flow. As a result, the oxidizing power of ozone sterilizes the bath water or decomposes fat, etc., and the bath water is cleaned, so the number of times the bath water is circulated can be dramatically increased. Therefore, it is possible to save bath water.

The circulation tank 2 is filled with a bathtub 1 by the operation of a pump 22.
A heating coil 8 is provided that heats the bathtub water drawn from inside by heat exchange. In this embodiment, the heating coil 8 is arranged so as to be wound around the activation tank 25.
The bathtub water flowing into the bathtub is heated. The heating coil 8 is supplied with high-temperature refrigerant gas from a heat pump 3, which will be described later, and heats the bathtub water through heat exchange. In Figure 1,
Thin arrows indicate the circulation path through which bath water is filtered and heated.

The heat pump 3 includes a compressor 31 that compresses refrigerant gas into high-temperature refrigerant gas, and a fan 3 that blows outside air onto refrigerant pipes to exchange heat.
2 is provided. This heat pump 3 generates a high temperature by compressing refrigerant gas using outside air as a heat source, and a conventionally known type is used.

The hot water tank 4 has a water inlet 41 formed at the bottom thereof,
A water outlet 42 is formed in the upper part, and the water outlet 42
Hot water for drinking, etc., is supplied from the indoor faucet (not shown). This hot water tank 4
A heating coil 6 is disposed inside to heat the water stored inside by heat exchange. In this embodiment, the heating coil 6 is provided at the lower part of the hot water tank 4, that is, on the side of the water inlet 41, and is designed to heat makeup water supplied into the hot water tank 4 via a fan 63. The heating coil 6, the heat pump 3, and the heating coil 8 are connected by a refrigerant path 7, and the refrigerant gas from the heat pump 3 heats the hot water in the bathtub 1 and the water in the hot water tank 4. It is becoming more and more popular. The refrigerant path 7 guides refrigerant gas from the compressor 31 of the heat pump 3 from the outlet 33 of the heat pump 3 to the inlet 81 of the heating coil 8, and from the outlet 82 of the heating coil 8 to the inlet 34 of the heat pump to the compressor. Heating coil side circulation system 71 returning to 31
Then, the refrigerant gas from the compressor 31 is guided from the outlet 33 of the heat pump 3 to the inlet 61 of the heating coil 6 of the hot water tank 4, and
2 and a heating coil side circulation system 72 that returns to the compressor 31. A switching means 9 for switching the refrigerant gas between the heating coil side circulation system 71 and the heating coil side circulation system 72 is disposed between the heating coil side circulation system 71 and the heating coil side circulation system 72. In this embodiment, this switching means 9 comprises a three-way valve, and is adapted to automatically switch the refrigerant gas. FIG. 1 shows an embodiment in which this switching is performed automatically. A temperature detector 10 such as a thermostat or a temperature sensor is provided in the bathtub 1, and the temperature detector 10 and the three-way valve 9 are controlled by a controller. 11
connected by. The controller 11 is provided with a circuit that can set the temperature of the bathtub water in advance and a circuit that switches the three-way valve 9, so that the refrigerant gas can be automatically switched depending on the temperature of the bathtub water. There is.

FIG. 2 is a flowchart showing control by the controller 11. A desired bath water temperature, for example 42 to 45°C, is set by the controller 11 (step a). The controller 11 compares the temperature information from the temperature detector 10 with the set temperature (step b), and if the temperature is below the set temperature,
A signal from the controller 11 opens the valve port of the heating coil side circulation system 71 and closes the valve port of the heating coil side circulation system 72 (step c). As a result, the high temperature refrigerant gas from the heat pump is guided to the heating coil 8 to heat the bathtub water (step d). During this heating, temperature information from the temperature sensor 10 is input to the controller 11 and is continuously or intermittently compared with a set temperature.
On the other hand, when the temperature information from the temperature detector 10 is higher than the set temperature, the valve port of the heating coil side circulation system 71 is closed by the signal from the controller 11, and the valve port of the heating coil side circulation system 72 is closed. Opening (step e) As a result, the hot water in the hot water supply tank 4 is heated (step f). Therefore, the refrigerant gas from the heat pump 3 is switched and used for heating the bathtub water or the hot water in the hot water supply tank under the control of the controller 11, and the heating of the bathtub hot water and the hot water in the hot water supply tank can be performed by a single heat pump. This makes it possible to save thermal energy. In FIG. 1, broken line arrows indicate a circulation system in which the refrigerant gas heats the bath water, and thick arrows indicate a circulation system in which the refrigerant gas heats the bath water. Note that the above control may be performed with priority given to heating the hot water tank 4. In this case, a temperature detector is provided within the hot water tank 4. Moreover, the temperature control of both the bathtub water and the hot water in the hot water supply tank 4 may be performed at the same time.

In FIG. 3, the hot water tank 4 is connected to the circulation tank 2 through the gap 12.
This is an embodiment in which the heat pump 3 is integrally attached to the heat pump 3, and by being integrated, the device can be made smaller and the installation space can be reduced.

Note that various modifications can be made to the present invention. For example, ozone may be introduced into the circulation tank without being ejected into the bathtub. Further, the heating coil may be disposed within the bathtub, or may be disposed separately within the tank to heat the bath water.

〔Effect of the invention〕

As described above, according to the present invention, the hot water in the bathtub is filtered and sterilized with ozone, and the bathwater is ion-exchanged in the activation tank to return it to its original water quality, which increases the effectiveness of bathing. The number of times the bath can be circulated is increased, making it possible to save on bath water. In addition, since the refrigerant from the heat pump is switched between heating the bathtub water and heating the bathtub water depending on the amount of thermal energy, it is possible to use thermal energy effectively, and power consumption can be reduced compared to conventional methods. As it becomes,
A single heat pump can heat hot water in the bathtub or hot water tank at any time, and there is no need to increase the capacity of the compressor, making the device more compact.
effective.

Since the temperature of the water in the bathtub can be set on the control device, there is no need for humans to monitor the rise in water temperature, and since the control device switches the refrigerant flow path, there is no need to over-boil the water, which saves time and effort. No heat energy is wasted.

Even if the outside air temperature is low, heat pumps can be operated continuously if a defrost device is attached, and since they heat the hot water tank for purposes other than heating bath water, the stored hot water in the hot water tank can be used at any time, making it easy to use.

[Brief explanation of drawings]

Fig. 1 is a piping system diagram of one embodiment of the present invention;
The figure is a flowchart of an example of automatic control, and FIG. 3 is a plan view of another embodiment. DESCRIPTION OF SYMBOLS 1... Bathtub, 2... Circulation tank, 3... Heat pump, 4... Hot water tank, 5... Sterilization means, 6... Heating coil, 7... Refrigerant path, 8... Warming coil, 9...
...Switching means, 10...Temperature detector, 11...Controller, 21...Filter, 22...Pump.

Claims (1)

[Scope of Claims] 1. A circulation tank that is connected to the bathtub by a pipe and is provided with a filtration device, a pump, and an activation tank, and that circulates bathwater between the bathtub and the bathtub, and a temperature sensor provided in the bathtub. a sterilizer that sterilizes the bath water by supplying ozone air into the bath water; a heating coil that heats the bath water by heat exchange; a hot water tank in which the heating coil is disposed; A heat pump equipped with a fan that blows air as a heat source into a refrigerant pipe line and a compressor that compresses the heated refrigerant into high-temperature gas, and a heat pump that circulates the refrigerant gas through the heating coil, the heating coil, and the heat pump. a refrigerant path connected to the refrigerant path; a switching means disposed in the refrigerant path for switching refrigerant gas from the heat pump between the heating coil and the heating coil; A circulating heating device for hot water, comprising: a control device that operates the switching means to cause the refrigerant to flow to the heating coil if the temperature is higher than the set temperature, and to flow to the heating coil if the temperature is lower.