KR101092495B1 - Waste heat recycle apparatus for solar thermal system - Google Patents

Abstract

The present invention provides a device utilizing the waste heat of the solar system: a three-way valve (24) to form a branch flow path in the low-temperature side pipe 11 and the high-temperature side pipe 12 of the collector 10, to change the flow path of the heat medium Solar system 20 provided; A heat recovery unit (30) having a radiator (34) on the branch flow path of the solar system (20), for sending hot air by waste heat to the duct (32); And a dryer 50 connected to a downstream end of the duct 32 to receive hot air and having a channel 54 on the plurality of passages 52.
Accordingly, the present invention has the effect of expanding the market demand by utilizing the productive use in addition to heating and hot water while improving safety by preventing overheating of the collector.

Description

Waste heat recycle apparatus for solar thermal system

The present invention relates to a waste heat utilization apparatus of a solar system, and more particularly, to a waste heat utilization apparatus of a solar system for use in productive use in addition to heating and hot water while improving safety by preventing overheating of a collector.

In general, the solar system is more developed and economically advantageous than other alternative energy in the use of heating and heating and hot water supply in houses. It is actively promoted. However, like other alternative energy sources such as wind and geothermal, the development of technology to improve safety and utilization in addition to economic feasibility is expected to be an important factor in expanding market share.

For example, according to the "Failure Diagnosis System of Solar System" of Korean Registered Utility Model Publication No. 0387031, a flow meter which is provided in the piping of the heat collecting section and measures the flow rate of the heat medium passing through the piping, and is provided in the piping of the heat storage section The regenerative flow detection sensor outputs an electric signal according to the flow pressure of the hot water passing through the inside, and the system uses the regenerative flow detection sensor signal, the flow rate measurement value, and the predetermined heat medium setting value when each circulation pump is operated. In the case of abnormal analysis, a configuration including a failure diagnosis controller for lighting a lamp corresponding to the analysis result is proposed.

It quickly alarms the failure of the solar system due to thermal fluid leakage due to the failure of pumps, solar collectors, piping, and various valves, overheating of the collectors, etc.But it is inevitable for manual measures and waste heat during overheating. There is a disadvantage that it is difficult to exhibit energy efficiency.

As another example, according to the "Solar Hot Water Heater" of Korean Registered Utility Model Publication No. 0445815, the hot water heating pipe connected to the hot water storage tank and the hot water storage tank is stored in the heat storage tank by using the hot water heat exchanger. This paper proposes a technology that maximizes the annual operation rate by eliminating the shortage of hot water supply and by heating hot water by using enough heated heating water during the period of no heating.

It aims to produce the second purpose of heating hot water by using the heated heating water as an extra surplus amount along with the first purpose of smooth collection through the prevention of trouble of air mixing, but for the purpose of production besides heating and cooling and hot water supply. There is room for improvement in terms of utilizing surplus calories.

"Fault diagnosis system of solar thermal system" of Korean Utility Model Publication No. 0387031 "Solar hot water heater" of Korean Registered Utility Model Publication No. 0445815

An object of the present invention for improving the conventional problems as described above is to provide a waste heat utilization apparatus of the solar system for use in productive use in addition to heating and hot water while improving safety by preventing overheating of the collector.

In order to achieve the above object, the present invention provides a device utilizing the waste heat of the solar system: a solar system having a three-way valve to form a branch flow path in the cold side pipe and the hot side pipe of the collector, and to change the flow path of the heat medium; A heat recovery unit having a radiator on a branch flow path of the solar system, and sending hot air by waste heat to a duct; And a dryer connected to the downstream end of the duct to receive hot air and having a channel on a plurality of passages.

In addition, according to the present invention, the heat recovery means is provided with a heater and a blowing fan at a downstream end of the duct.

In addition, according to the present invention, the duct of the heat recovery means is characterized in that it further comprises a flexible pipe at least in part to facilitate the removal and deformation.

In addition, according to the present invention, the dryer is characterized in that it comprises an inlet flow path plate to be opened and closed to intercept the flow path of hot air passing through the coal tray, and a discharge flow path plate to be opened and closed to control the hot air flow path not passing through the coal tray.

On the other hand, the terms or words used in the present specification and claims are not to be construed as limiting the ordinary or dictionary meanings, the inventors should use the concept of the term in order to explain the invention in the best way. It should be interpreted as meanings and concepts corresponding to the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention, and various alternatives may be substituted at the time of the present application. It should be understood that there may be equivalents and variations.

As described above, according to the waste heat utilization apparatus of the solar system according to the present invention, the overheating of the collector is prevented from occurring, thereby improving safety and utilizing the product for heating and hot water supply in a productive use, thereby expanding market demand.

1 is a block diagram showing the connection state of the main part of the device according to the present invention;
2 is a block diagram showing the terminal of the apparatus according to the invention terminated,
3 is a configuration diagram showing a modification of the device according to the invention.

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

1 is a block diagram showing the connection state of the main part of the device according to the present invention, FIG. .

The present invention relates to a device utilizing waste heat generated in a solar heating and hot water supply system. In particular, the main target is the waste heat due to overheating of the collector 10, but may be used in combination with the energy of heating and hot water supply. The collector 10 is shown based on a flat plate type, but is also applied to a vacuum tube type, a light collecting type, a mixed type, and the like.

The solar system 20 according to the present invention is characterized in that a branch flow path is formed in the low temperature side pipe 11 and the high temperature side pipe 12 of the collector 10 and has a three-way valve 24 to change the flow path of the heat medium. Have Typically, the solar system 20 is connected to the collector 10 via the low temperature side tube 11 and the high temperature side tube 12 to form a heat medium circulation path. The heat medium circulates in the heat storage tank 22 to store heat energy by use of heat and heat exchange, and the heat energy stored in the water used in the heat storage tank 22 is sent to the heating pipe 26 and the hot water supply pipe 28. The temperature sensor 15 is installed in the high temperature side pipe 12 so as to sense overheating of the collector 10.

At this time, if the heat load of the heating pipe 26 and the hot water supply pipe 28 is not large and the thermal energy of the heat storage tank 22 is sufficient, the collector 10 may be burned out by overheating, so the low temperature side pipe 11 and the high temperature side pipe 12 A branch flow path is formed in the column) and the heat exchange is performed while the flow path is changed by the three-way valve 24. In particular, the portion branched from the high-temperature side pipe 12 is selected as the position closest to the collector 10, and a three-way valve 24 is installed at the branch portion.

In addition, according to the present invention, the heat recovery means 30 is provided with a radiator 34 on the branch flow path of the solar system 20, and serves to send hot air by waste heat to the duct 32. The radiator 34 is installed together with the blower 36 on the wall surface of the solar system 20 to which the upstream end of the duct 32 is connected. Usually, the duct 32 has a steel plate structure having a circular or square cross section, but a steel pipe or a heat resistant resin pipe may be used. The duct 32 is used for drying grains by sending waste heat generated when the collector 10 is overheated to a dryer 50 to be described later.

At this time, the heat recovery means 30 of the present invention is provided with a heater 44 and a blowing fan 46 at the downstream end of the duct (32). When the collector 10 does not reach an overheated state during the winter or rainy season, the heater 44 and the blower fan 46 installed at the downstream end of the duct 32 may be operated to dry the dryer 50. Make sure

In addition, according to the present invention, a dryer 50 having a channel 54 on a plurality of passages 52 is connected to receive hot air at a downstream end of the duct 32. The dryer 50 has a sealed box structure in which at least one surface thereof is opened, and a plurality of air passages 52 are formed therein, and a plurality of pores 54 having pores are releasably stacked on the air passages 52. The downstream end of the duct 32 is connected to the air passage formed in the lower portion of the dryer 50 in a flanged manner. The heater 44 and the blowing fan 46 located at the downstream end of the duct 32 may be installed to actually span the air passage inside the dryer 50.

At this time, the dryer 50 is the inlet flow path plate 56 that is opened and closed to control the hot air flow path passing through the channel 54, and the discharge flow path plate to be opened and closed to control the hot air flow path not passing through the channel 54 ( 58). The air passage of the dryer 50 forms a passage through which the channel 54 passes from one side to an upper side and a passage discharged as it is to the other side. The inflow passage plate 56 is provided in the former flow path, and the discharge flow path plate 58 is provided in the latter flow path. The inflow flow path plate 56 and the discharge flow path plate 58 perform the opening and closing operation of the flow path by a driving means such as a solenoid, and normally use the waste heat of the solar system 20 in the dryer 50, but in some cases, To be discharged.

On the other hand, the duct 32 of the heat recovery means 30 may be further provided with a flexible pipe 42 in at least a portion to facilitate attachment and detachment. The solar system 20 is installed in place, but the dryer 50 takes into account that the place can be moved somewhat. When one or two flexible pipes 42 are installed in the middle of the duct 32 in a flange or hose clamp manner, the dryer 50 can be quickly moved and the vibration generated during the transportation of hot air can be alleviated to improve durability. It is advantageous to.

In operation, if the heat load of the heating pipe 26 and the hot water supply pipe 28 is not large in summer, the heat medium temperature of the collector 10 rises, and when the signal of the temperature sensor 15 exceeds the set value, the three-way valve 24 ), And the blower 36 is operated while bypassing the high temperature heat medium to the branch flow path on the radiator 34 side, and the heat medium cooled by the heat radiation is sent to the heat collector 10 or the heat storage tank 22 again, The hot air heat exchanged through the 34 passes through the duct 32 of the heat recovery means 30 and flows into the dryer 50.

At this time, if the inflow passage plate 56 is completely opened and the exhaust passage plate 58 is completely closed, the entire waste heat can be introduced into the dryer 50, and the inflow passage plate 56 is completely closed and the discharge passage plate 58 is closed. If you open all), you can discharge the entire waste heat as it is. That is, the opening amount is controlled by the inflow passage plate 56 and the discharge passage plate 58 according to the heat amount currently consumed on the dryer 50.

On the contrary, if the heat load of the heating pipe 26 and the hot water supply pipe 28 is large in winter, the rising width (overheating state) of the heat medium temperature of the collector 10 is reduced, so that the number of operations of the radiator 34 is reduced and sent to the duct 32. The temperature of the air is lowered. In this case, although the heater 44 and the blowing fan 46 installed adjacent to the dryer 50 downstream of the duct 32 should be operated and sent to the dryer 50, the heating pipe 26 and the hot water supply pipe 28 are provided. If the heat load is not great, even if the collector 10 is not in an overheated state, the three-way valve 24 may be operated to add hot air.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

10: collector 11: low temperature side pipe
12: high temperature side pipe 15: temperature sensor
20: solar system 22: heat storage tank
24: 3-way valve 30: heat recovery means
32: duct 34: radiator
36, 46: blower fan 42: flexible tube
44: heater 50: dryer
52: passage 54: dumping
56: flow path plate 58: flow path plate

Claims (4)

For devices that utilize waste heat from solar systems:
A solar heat system 20 having branched flow paths formed in the low temperature side pipe 11 and the high temperature side pipe 12 of the collector 10 and having a three-way valve 24 to change the flow path of the heat medium;
A heat recovery unit (30) having a radiator (34) on the branch flow path of the solar system (20), for sending hot air by waste heat to the duct (32); And
And a dryer (50) connected to the downstream end of the duct (32) to receive hot air and having a channel (54) on the plurality of passages (52). . The method of claim 1,
The heat recovery means (30) is a waste heat utilization apparatus of the solar system, characterized in that it comprises a heater (44) and a blowing fan (46) at the downstream end of the duct (32). The method of claim 1,
The duct 32 of the heat recovery means 30 further comprises a flexible pipe 42 at least in part so that attachment and detachment and deformation are easy. The method of claim 1,
The dryer 50 includes an inlet flow path plate 56 that opens and closes to intercept a flow path of hot air passing through the tray 54, and a discharge flow path plate 58 that opens and closes to control the hot air path that does not pass through the tray 54. Waste heat utilization apparatus of the solar system, characterized in that it comprises a.

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