KR200400238Y1 - Waste heat collecting device combined with ozone device - Google Patents

Abstract

The present invention relates to a waste heat recovery apparatus combined with an ozone device, in particular a waste heat source hot water source, a heat pump to generate cold water, hot water or cold / hot water using waste heat source hot water supplied from the waste heat source hot water source, Turbine pump for injecting and pumping together ozone gas generated from ozone generator into cold water, hot water or cold / hot water and a mixture of ozone gas and water pumped by the turbine pump in a predetermined space for purification and purification In the waste heat source hot water source, which is a facility for maintaining a constant water temperature, such as a bath or swimming pool, comprising an ozone device is combined, characterized in that it comprises one or more reactors for supplying the waste heat source to the hot water source. By utilizing this, the energy efficiency can be increased and the maintenance cost can be reduced. In addition, it is possible to supply cold and hot water sterilized, deodorized, decolored, and purified through an ozone purifying device, and promotes a reaction during sterilization, deodorized, decolorized, and purified, thereby minimizing deterioration of cold and hot water, thereby increasing energy efficiency.

Description

Waste heat recovery unit combined with ozone unit {WASTE HEAT COLLECTING DEVICE COMBINED WITH OZONE DEVICE}

The present invention relates to a waste heat recovery device combined with an ozone device, in a waste heat source hot water supply source that is a facility that maintains a constant water temperature, such as a bath or a swimming pool, and by utilizing this, it is possible to increase energy efficiency, thereby reducing maintenance costs. The ozone purifier can supply sterilized, deodorized, decolorized, and purified cold and hot water, and promotes the reaction during sterilization, deodorizing, decoloring, and purification, and minimizes the deterioration of cold and hot water. It relates to a combined waste heat recovery device.

In general, waste heat hot water sources such as baths, swimming pools and hot springs are operated to maintain a constant temperature at all times, and waste heat generated by discharging the waste hot water as it is, thus wastes enormous heat energy. Has been.

In the past, various applications such as Utility Model Registration Nos. 2000-9866, 2004-14196, and 2002-33200 have been made. However, the waste heat recovery apparatus utilizing the waste hot water concentrated only on the waste heat recovery of the waste hot water, and did not consider the environmental pollution problem and the recycling of the waste water as water due to the discharge of the waste water. By combining wastewater recovery and ozone sterilizers and combining them more efficiently, the company can save energy, recycle energy resources, and recycle water resources. It is necessary to develop a device that provides water that is harmless to the human body and a combination technology thereof.

In order to solve the problems of the prior art as described above, the present invention can reduce the maintenance cost by utilizing energy from the waste heat source hot water source, and at the same time can supply sterilized, deodorized, decolorized, purified cold and hot water through an ozone purification device. In addition, it is an object of the present invention to provide a waste heat recovery device combined with an ozone device that can increase the energy efficiency by promoting the reaction in the sterilization, deodorization, decolorization, purification process to minimize the deterioration of cold and hot water.

In addition, the present invention not only recycles energy resources, but also recycles water resources, and provides a waste heat recovery device incorporating an ozone device that provides harmless water to humans with a highly efficient system in terms of environment and induces harmless wastewater discharge. It aims to do it.

In order to achieve the above object, the present invention

Waste heat source hot water source;

A heat pump configured to generate cold water, hot water or cold / hot water by using the waste heat source hot water supplied from the waste heat source hot water source;

A turbine pump for pumping together the cold water, hot water, or cold / hot water by introducing ozone gas generated from an ozone generator; And

The ozone device is characterized in that it comprises one or more reactors for maintaining the mixture of ozone gas and water pumped by the turbine pump in a predetermined space to purify and then supply the purified water to the waste heat source hot water supply source To provide a waste heat recovery device.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a waste heat recovery apparatus combined with an ozone device, a heat pump for generating cold water, hot water or cold / hot water using waste heat source hot water source, waste heat source hot water supplied from the waste heat source hot water source, the cold water, Turbine pump 10 for pumping together the ozone gas generated from the ozone generator into hot or cold / hot water and the mixture of ozone gas and water pumped by the turbine pump 10 in a predetermined space to purify and react And one or more reactors for supplying the purified water to the waste heat source hot water source.

That is, as shown in FIG. 1, the waste heat recovery apparatus combined with the ozone device of the present invention uses various waste heat sources having waste heat source hot water as its source, and specific examples thereof include baths, hot springs, Swimming pools; The waste heat source hot water supplied from the waste heat source hot water source acts as an energy source to the heat pump, and thus, cold water, hot water, or cold / hot water using waste heat source hot water supplied from the waste heat source hot water source as shown in FIG. 1. Supplied to a heat pump to produce.

The heat pump may be a heat pump used in various well-known waste heat recovery devices that can provide cold water, hot water or cold and hot water together using waste heat, and specific examples thereof may be applied to the utility model registration application 2000 described above. Various heat pumps such as heat pumps and heat pumps using heat pipes as described in -9866, 2004-14196, 2002-33200, etc. can be applied thereto. Such heat pumps may utilize a waste heat to produce only cold water, provide only hot water, provide hot water, or produce cold and hot water, respectively, to supply cold and hot water to supply all of them. This is a technique that is applied to a variety of.

In addition, as shown in FIG. 1, the heat exchanger of the heat exchanger may be made smoothly, and a filter may be further provided at the front of the heat pump to prevent the heat exchanger surface from being blocked by foreign matter.

As a preferable example of this, a heat pump of the type shown in FIG. 2 may be applied. That is, the heat pump is a heat exchanger for heating the working fluid with hot water supplied from the waste heat source hot water supply source, a compressor for compressing and pressurizing the heated working fluid, the working fluid from the compressor is condensed and accordingly heat A heat exchange condenser to be produced, a hot water tank connected to the heat exchanger of the heat exchanger condenser, and supplying the generated hot water to the turbine pump, an expansion valve to expand the working fluid heat-exchanged in the heat exchange condenser, and a working fluid from the expansion valve. It may be configured to include a heat exchange evaporator for evaporating to thereby generate cold water by the endotherm and a cold water tank connected to a heat exchanger of the heat exchanger evaporator and supplying the generated cold water to the turbine pump. As the heat exchanger, various heat exchangers of a fin coil and a fin plate type may be applied thereto, and the heat pump using the refrigerant may include not only the above-described configuration but also various known modifications.

Through the heat pump, the waste heat source hot water transfers energy to the heat pump through a heat exchanger and is drained as shown in FIGS. 1 and 2, and the heat pump produces cold water, hot water, or cold / hot water using the energy. .

The cold water, hot water, or cold and hot water thus produced is supplied as a bath water, a pool water or a drinking water as a hot water source of waste heat source, which requires sterilization, deodorization, decolorization, disinfection and purification to be suitable for use before the supply. . Therefore, for this purpose, as shown in FIG. 1, an ozone generator is separately provided, and a turbine pump 10 for pumping together the ozone gas generated from the ozone generator into the cold water, hot water, or cold / hot water is pumped together. As shown in FIG. 3, the turbine pump 10 comprises an impeller 30 formed by a plurality of blades as a pump head, and has a function of smoothly transferring gas and liquid even when mixed with the pump head. Therefore, the ozone gas and water generated in the ozone generator may be absorbed through the inlet pipes 40 and 50, respectively, mixed with each other, and discharged and transported together. Preferably the turbine pump is a vortex turbine pump for the transport of gas-liquid mixture. Through this, the mixing of water and ozone is made more active through the pumping process, so it is not necessary to equip the mixing tank like the existing aeration tank, and the equipment can be easily decorated, and the practical use is reduced by reducing the reaction time in the subsequent reaction tank. This prevents cold or hot water from approaching room temperature during the ozone water treatment process, improving energy efficiency and preventing energy loss.

Therefore, the gas-liquid mixture passing through the turbine pump maintains a mixture of ozone gas and water pumped by the turbine pump in a predetermined space and purifies through an oxidation reaction. It is reacted in the reactor via one or more reactors supplied to the source, and is supplied after sterilization, deodorization, decolorization, purification and disinfection. That is, cold / hot water reacted with ozone in the turbine pump head by using sterilization, deodorization, and decolorization capabilities of ozone are primary sterilization water purification and secondary sterilization water purification in the reaction tank. The pressure inside the reactor is kept constant at 0.5-1 kgf / cm ² using a pressure gauge as shown in FIG. 1 to maintain a contact time for ozone and cold / hot water to react. It can supply and produce hot water, swimming pool water, shower water, drinking water, etc.

In addition to this, as shown in FIG. 4, a second turbine pump 15 for introducing the ozone gas generated from the ozone generator into the waste heat source hot water and the pump is pumped together between the waste heat source hot water source and the heat pump. Can be configured. The second turbine pump 15 may have the same type as the turbine pump 10, and the ozone generator may be configured separately from the ozone generator connected to the above described turbine pump as shown in FIG. Alternatively, one ozone generator may be used to supply ozone to both turbine pumps 10 and 15. This purifies the wastewater discharged to the outside after passing through the heat pump and at the same time, turbulence is formed in the water in contact with the surface of the heat exchanger as the gas-liquid mixture flows, thereby increasing heat exchange efficiency. Through the sterilization effect, it is possible to prevent contamination of the heat exchanger surface with contaminants by reducing the contamination of waste water in contact with the surface of the heat exchanger, and to prevent deterioration of heat exchange efficiency due to the adsorption of contaminants. In addition, maintenance costs can be reduced by lengthening the maintenance period according to the contamination of the surface of the heat exchanger.

In addition, as shown in FIG. 5, after the mixture of the ozone gas and the water discharged through the heat pump is maintained in a predetermined space for purification reaction, a part of the purified water is supplied to the refill water of the cold water tank or the hot water tank. It may be configured to further include one or more second reactor. Through this, when discharged into the waste water, it is possible to obtain a further effect of recycling water resources by recycling a part of the water. The second reactor may be configured in the same manner as the reactor described above.

According to the waste heat recovery apparatus combined with the ozone apparatus of the present invention as described above, since the mixing of water and ozone is more actively performed through the pumping process of the turbine pump, there is no need to separately provide a mixing tank such as an existing aeration tank. It can be simple to reduce the cost of manufacturing equipment, and to reduce the reaction time in the subsequent reaction tank to prevent the cold water or hot water from approaching the room temperature during the ozone water treatment process before actual use, thereby improving energy efficiency and energy. There is an advantage to prevent the loss.

In addition, it is possible to purify the wastewater discharged to the outside after passing through the heat pump and to increase the heat exchange efficiency of the heat exchanger according to the inflow of the gas-liquid mixture, and to increase the heat exchange efficiency according to the contamination of the surface of the heat exchanger. In addition, there is an advantage that can reduce the maintenance cost by having a long maintenance period.

In addition, when oil is discharged into waste water, a portion of water may be recycled after ozone treatment, thereby further reusing water resources.

The present invention described above is not limited to the detailed description of the above-described invention and the accompanying drawings, and those skilled in the art without departing from the spirit and scope of the present invention described in the utility model registration claims below. Various modifications and changes are also included within the scope of the present invention.

1 is a block diagram showing an overall system according to an embodiment of the waste heat recovery apparatus combined with the ozone apparatus of the present invention.

Figure 2 is a block diagram showing in detail an embodiment of the heat pump used in the waste heat recovery apparatus combined with the ozone apparatus of the present invention.

Figure 3 is a schematic diagram showing the function of the pump head of the turbine pump used in the waste heat recovery apparatus combined with the ozone device of the present invention.

Figure 4 is a block diagram showing the overall system according to another embodiment of the waste heat recovery apparatus combined with the ozone apparatus of the present invention.

Figure 5 is a block diagram showing an overall system according to another embodiment of the waste heat recovery apparatus combined with the ozone apparatus of the present invention.

Explanation of symbols on main parts of drawing

10 turbine turbine 15 second turbine pump

20: pressure gauge 30: impeller

40: pump head housing 50: ozone inlet pipe

60: water inlet pipe 70: gas-liquid mixture discharge pipe

Claims (4)

Waste heat source hot water source; A heat pump configured to generate cold water, hot water or cold / hot water by using the waste heat source hot water supplied from the waste heat source hot water source; A turbine pump pumping together ozone gas generated from an ozone generator into the cold water, hot water, or cold / hot water; And The ozone device is characterized in that it comprises one or more reactors for maintaining the mixture of ozone gas and water pumped by the turbine pump in a predetermined space to purify and then supply the purified water to the waste heat source hot water supply source Waste heat recovery device. The method of claim 1, The heat pump is A heat exchanger for heating the working fluid with hot water supplied from the waste heat source hot water source; A compressor for compressing and pressing the heated working fluid; A heat exchange condenser condensing the working fluid from the compressor and thereby producing hot water with heat; A hot water tank connected to the heat exchanger of the heat exchanger condenser and supplying the generated hot water to the turbine pump; An expansion valve for expanding a working fluid heat exchanged in the heat exchange condenser; A heat exchange evaporator for evaporating the working fluid from the expansion valve to thereby generate cold water by endotherm; And, And a cold water tank connected to a heat exchanger of the heat exchanger evaporator and supplying the generated cold water to the turbine pump. The method according to claim 1 or 2, And a second turbine pump injecting ozone gas generated from an ozone generator into the waste heat source hot water and pumping the waste heat source between the hot water supply source and the heat pump. The method of claim 3, After maintaining the mixture of ozone gas and water discharged through the heat pump in a predetermined space to purify the reaction, and further comprises one or more second reaction tank for supplying a portion of the purified water to the refill water of the cold water tank or hot water tank Waste heat recovery device is combined with an ozone device.