JP2014017068A - Exhaust heat utilization system of power storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exhaust heat utilization system of a power storage device capable of utilizing exhaust heat of a power storage device with a simple configuration.SOLUTION: An exhaust heat utilization system 200 of a power storage device 40 includes a power storage device 40 which can charge and discharge power utilized in a house 100, heat storage materials 214, 214, ... housed in the floor 205 of a living 109 in the house 100, a fan 202 for supplying air warmed with exhaust heat from the power storage device 40, and hollow members 213, 213, ... for ventilating the floor 205 with the air supplied by the fan 202. The hollow members 213, 213, ... stores heat of the air, passing through the hollow members 213, 213, as the heat source.

Description

  The present invention relates to a technology of a waste heat utilization system for a power storage device that uses waste heat of a power storage device.

  Conventionally, a power storage device capable of charging and discharging electric power used in buildings emits exhaust heat due to charge and discharge efficiency when charging and discharging electric power, but in many cases the exhaust heat is used. It is discharged without. On the other hand, a technique using the exhaust heat of the power storage device is known. For example, as described in Patent Document 1.

  In the technique described in Patent Literature 1, a heat storage material is disposed in the power storage device so as to surround the battery. Further, a heat medium circulation pipe through which the heat medium circulates is wound around the heat storage material. As a result, heat is stored in the heat storage material by the exhaust heat of the power storage device, the heat medium is heated by releasing the stored heat, and the heated heat medium is circulated through the heat medium circulation pipe to store the heat. The exhaust heat of the device is used.

  However, since the technology described in Patent Document 1 is arranged so that the heat storage material surrounds the battery of the power storage device, the heat storage material is controlled not to take too much heat from the battery, or the heat storage material stores heat. It is disadvantageous because complex control (configuration) is required to use the exhaust heat of the power storage device, such as controlling the amount of heat stored and controlling the amount of heat released from the heat storage material. Met.

JP 2009-266556 A

  The present invention has been made in view of the above situation, and a problem to be solved is to provide a waste heat utilization system for a power storage device that can use the waste heat of the power storage device with a simple configuration. It is.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in Claim 1, it is warmed by the electrical storage apparatus which can be charged / discharged the electric power utilized in a building, the floor heating thermal storage material accommodated in the floor part of the indoor of the said building, and the exhaust heat of the said electrical storage apparatus A fan for blowing the generated air and a ventilation part for allowing the air blown by the fan to be ventilated to the floor part, and the floor heating heat storage material stores heat using the air ventilating the ventilation part as a heat source. To do.

  In claim 2, further comprising: a discharge part capable of discharging the air blown by the fan without passing through the ventilation part; and an opening / closing switching means for switching between opening and closing of the ventilation part and the discharge part, When heat is not stored in the floor heating heat storage material, the opening / closing switching means switches between opening and closing of the ventilation section and the discharge section, and the air blown by the fan is discharged from the discharge section.

  In Claim 3, the 1st detection means which detects the temperature of the air warmed by the exhaust heat of the said electrical storage apparatus, the 2nd detection means which detects the temperature of the said indoor or the outdoor air, and the said open / close switching means Control means for controlling switching between opening and closing of the ventilation part and the discharge part by the control means, the control means according to the detection results detected by the first detection means and the second detection means, The opening / closing switching means controls switching between opening and closing of the ventilation section and the discharge section.

  In Claim 4, the said floor heating thermal storage material is one member which comprises warm water floor heating or electric floor heating.

  In Claim 5, the said floor part comprises the hollow member which has the hollow structure extended in the parallel direction with respect to the floor surface of the said floor part, and the said ventilation | gas_flowing part is formed with the said hollow member. is there.

  As effects of the present invention, the following effects can be obtained.

  In claim 1, the exhaust heat of the power storage device can be used with a simple configuration. More specifically, in claim 1, floor heating can be performed by using the exhaust heat of the power storage device with a simple configuration.

  In the second aspect, when floor heating is not performed, air warmed by the exhaust heat of the power storage device can be appropriately discharged with a simple configuration, and the temperature of the power storage device can be prevented from increasing.

  In claim 3, even if it does not respond to a resident's operation, according to the detection result of the 1st detection means and the 2nd detection means, and the condition preset to the control means, it uses exhaust heat of an electrical storage device. Whether the floor heating is performed or whether the air heated by the exhaust heat of the power storage device is discharged without performing the floor heating can be controlled with a simple configuration.

  In claim 4, for example, an electric charge (or a gas charge) when hot water floor heating (or electric floor heating) is performed by using air heated by exhaust heat of the power storage device as an auxiliary heat source for floor heating. ) And the like can be suppressed.

  According to the fifth aspect of the present invention, since it is not necessary to provide a member dedicated to the discharge path of the air heated by the exhaust heat of the power storage device such as an exhaust duct, the installation cost can be reduced and the installation space can be made more efficient. .

The top view which showed the 1st floor part of the house which comprises the exhaust-heat utilization system of the electrical storage apparatus which concerns on one Embodiment of this invention. The block diagram which showed the electric power supply system which a house comprises. The side surface cross-sectional schematic diagram which showed the state by which the waste heat utilization system of the electrical storage apparatus was installed. The system diagram which showed the structure of the waste heat utilization system of an electrical storage apparatus. FIG. 5 is a schematic cross-sectional view taken along the line AA in FIG. 4. (A) The disassembled perspective view which showed the structure of the upper opening / closing mechanism and the lower opening / closing mechanism. (B) The perspective view which showed the structure of the state in which the upper opening / closing mechanism and the lower opening / closing mechanism are closed. (C) The perspective view which showed the structure of the state in which the upper opening / closing mechanism and the lower opening / closing mechanism are open. The side surface cross-section schematic diagram which showed the structure in case the waste heat utilization system of an electrical storage apparatus exists in a 1st state. The side surface cross-section schematic diagram which showed the structure in case the waste heat utilization system of an electrical storage apparatus exists in a 2nd state. The schematic diagram which showed the structure in case the waste heat utilization system of an electrical storage apparatus exists in a 2nd state in FIG. The side surface cross-section schematic diagram which showed the structure in case the waste heat utilization system of an electrical storage apparatus exists in a 3rd state. The system figure which showed the structure of the waste heat utilization system of the electrical storage apparatus which concerns on another embodiment of this invention. FIG. 12 is a schematic cross-sectional view taken along the line CC in FIG. 11.

  First, the overall configuration of a house 100 (only the first floor portion) including the exhaust heat utilization system 200 of the power storage device 40 according to an embodiment of the present invention will be described with reference to FIG. The present invention is not limited to being applied to a house, but can be widely applied to various buildings such as office buildings, station buildings, hotels, and the like.

  On the first floor of the house 100, an entrance 101, an entrance hall 102, a corridor 103, a toilet 104, a folding staircase 105, a staircase storage 106, a deck 107, a garage 108, and a living room 109 are arranged.

  An entrance 101 is arranged in the northeast part of the house 100, and an entrance hall 102 is arranged on the southwest side of the entrance 101. On the west side of the entrance hall 102, a corridor 103 extends in the west direction. On the north side of the corridor 103, a toilet 104 and a folding staircase 105 are arranged along the outer wall 100a of the house 100 in order from the east to the west. A living room 109 is arranged on the west side of the hallway 103. Further, a lower staircase storage 106 is disposed below the folded staircase 105.

  A power storage device storage chamber 110 is disposed in the staircase storage 106, and a power storage device 40 described later is further disposed in the power storage device storage chamber 110.

  A deck 107 is arranged on the west side of the corridor 103 and on the south side of the living room 109 (southwest part of the house 100). A garage 108 is arranged on the east side of the deck 107 (southeast part of the house 100).

  Next, the power supply system 1 provided in the house 100 will be described with reference to FIG.

  The power supply system 1 is provided in a house 100 and supplies power from a commercial power supply 90 and power generated by natural energy to a specific load. The power supply system 1 mainly includes a power generation unit 10, a power conditioner 20, a distribution board 30, a power storage device 40, a load 50 (specific load), other loads 80, a home server 60, a portable terminal 70, and the like. .

  The power generation unit 10 is a device that generates power using sunlight, and includes a solar cell panel or the like. The power generation unit 10 is installed on the roof of the house 100 (see FIG. 3).

The power conditioner 20 has a function of converting the DC power generated by the power generation unit 10 into AC power and matching the voltage, frequency, and phase of the commercial power supply 90. The power conditioner 20 is connected to the power generation unit 10.
The power conditioner 20 is provided with an operation changeover switch 20a for switching ON and OFF of the “self-sustaining operation mode” at the time of a power failure (when power from the commercial power supply 90 cannot be supplied).
The power conditioner 20 is connected to an emergency outlet 21 for taking out power from the power generation unit 10 at the time of a power failure (emergency).

The distribution board 30 is a collection of earth leakage breakers, wiring breakers, control units, and the like. The distribution board 30 is connected to the power conditioner 20 and the commercial power supply 90.
The distribution board 30 has a charge / discharge outlet group 31 (more specifically, a charge described later in the charge / discharge outlet group 31) for the power storage device 40 described later to charge, discharge, and exchange information (data). Only outlet 32 and LAN outlet 33) are connected.

  The charging / discharging outlet group 31 includes a charging outlet 32, a LAN outlet 33, and a discharging outlet 34.

The power storage device 40 charges power and discharges the charged power. The power storage device 40 according to the present embodiment includes a lithium ion battery that can charge and discharge power, an inverter that converts DC power from the lithium ion battery into AC power, and the like.
The power storage device 40 is connected to the emergency outlet 21 via a cable 41 for charging during a power failure (emergency).
In addition, the power storage device 40 is connected to the charging outlet 32 of the charging / discharging outlet group 31 via the charging cable 42 in the normal state, and to the discharging outlet 34 of the charging / discharging outlet group 31 via the discharging cable 43. Are connected to each other.
The power storage device 40 is connected to the LAN outlet 33 of the charging / discharging outlet group 31 via the LAN cable 44.

The load 50 is an electrical appliance or the like that consumes electric power in a house, and is a “specific load” that needs to supply electric power even during a power failure (emergency).
In the present embodiment, a living outlet 51 provided in the living room 109, a refrigerator 52, and a living lighting 53 provided in the living room 109 are used as the load 50 (specific load). In addition, a television 51a is connected to the living outlet 51.
Each of the loads 50 is connected to the power storage device 40 indirectly (in the present embodiment, via the discharge outlet 34 of the charge / discharge outlet group 31 and a leakage breaker not shown).

The other loads 80 are electrical appliances that consume electric power in the house 100, and unlike the above-described load 50 (specific load), it is not necessary to supply power during a power outage (emergency) ( The load is less likely to supply power in an emergency. Examples of the other loads 80 include an outlet and a lighting provided outside the living room 109.
The other loads 80 are connected to the distribution board 30.

The home server 60 is a control unit that manages information in the power supply system 1.
Home server 60 is connected to distribution board 30. The home server 60 can exchange information with the power conditioner 20, the power storage device 40, and the like, and can control the operation of the power conditioner 20, the power storage device 40, and the like.

The portable terminal 70 is for a resident of the house to check the state of the power supply system 1 or to perform an operation for changing the operation state of the power supply system 1. As the portable terminal 70, a touch panel combining a display device and an input device can be used.
The portable terminal 70 can exchange information with the home server 60 wirelessly.

  Next, with reference to FIG. 2, a description will be given of a power supply mode when power from the commercial power supply 90 is supplied without any problem in the power supply system 1 configured as described above.

  Normally, that is, when the electric power from the commercial power supply 90 can be supplied without any problem, the operation changeover switch 20a of the power conditioner 20 is turned off by the resident. In this case, the self-sustained operation mode of the power conditioner 20 is turned off, and power cannot be taken out from the emergency outlet 21 of the power conditioner 20.

  In this state, the DC power generated in the power generation unit 10 is converted into AC power in the power conditioner 20 and supplied to the distribution board 30. Further, AC power from the commercial power supply 90 is also supplied to the distribution board 30.

The electric power supplied from the power generation unit 10 and the commercial power supply 90 to the distribution board 30 is charged to the power storage device 40 via the cable 42 in an appropriate time zone. The charging time period can be arbitrarily set using the portable terminal 70. For example, if it is set to charge at midnight, midnight power with a low charge can be charged to the power storage device 40. Moreover, if it sets so that the electric power from the electric power generation part 10 may be charged in the time zone when sunlight of daytime is fully irradiated, the electric power generated using the natural energy (sunlight) in the said electric power generation part 10 will be used. The power storage device 40 can be charged.
In this case (normal time), when the power storage unit 40 is charged with power from the power generation unit 10 and the commercial power supply 90, power is simultaneously supplied (discharged) from the power storage device 40 to the other load 80. There is nothing. Thus, by preventing charging and discharging from being performed at the same time, deterioration of the power storage device 40 (more specifically, the storage battery (lithium ion battery) in the power storage device 40) can be prevented.

  Further, the power supplied from the power generation unit 10 and the commercial power supply 90 to the distribution board 30 is supplied to the other loads 80. In other words, the resident can use a device connected to an outlet provided outside the living room 109 or turn on lighting or the like other than the living room 109 with the electric power from the power generation unit 10 and the commercial power supply 90.

  In addition, when the power consumed by the other loads 80 can be adequately provided only by the power from the power generation unit 10, it is possible not to use the power from the commercial power supply 90. As a result, it is possible to save power charges.

Furthermore, the power charged in the power storage device 40 can be supplied to the load 50 via the cable 43. The time zone for supplying power from the power storage device 40 to the load 50 can be arbitrarily set using the portable terminal 70. For example, by setting power charged at midnight to the load 50 in the daytime, the power charge can be saved.
In normal times, when power is supplied (discharged) from the power storage device 40 to the load 50, power from the power generation unit 10 and the commercial power supply 90 is not charged to the power storage device 40 at the same time. Thus, by preventing charging and discharging from being performed at the same time, deterioration of the power storage device 40 (more specifically, the storage battery (lithium ion battery) in the power storage device 40) can be prevented.

As described above, control for supplying power from the power generation unit 10, the commercial power supply 90, and the power storage device 40 to the load 50 and other loads 80 as appropriate is performed based on the control program stored in the home server 60.
In addition, the power supply state as described above is displayed on the display device of the portable terminal 70, and the resident can check the power supply state with the portable terminal 70.

  Next, a power supply mode at the time of a power failure (when power from the commercial power supply 90 cannot be supplied) will be described.

  In the event of a power failure (emergency), the power system from the commercial power supply 90 to the distribution board 30 and the power system from the power conditioner 20 to the distribution board 30 (distribution of power) so as not to hinder the power restoration work of the power company. Electric power is not sent to the power system via the panel 30. Therefore, the power from the power generation unit 10 and the commercial power supply 90 is not charged into the power storage device 40 via the distribution board 30. On the other hand, the electric power charged in the power storage device 40 can be supplied (discharged) to the load 50 via the cable 43. That is, even when a power failure occurs, when the switch of the load 50 is turned on, the load 50 (the television 51a or the like) can be used using the power charged in the power storage device 40.

Further, at the time of this power failure (emergency), the resident switches the operation switch 20a of the power conditioner 20 to ON. As a result, the self-sustained operation mode of the power conditioner 20 is turned on, and power can be taken out from the emergency outlet 21 of the power conditioner 20.
However, the operation changeover switch 20a can be configured to transmit information detected as a power failure in the distribution board 30 to the power conditioner 20 and to be automatically turned ON.

  In this state, the electric power generated in the power generation unit 10 is charged into the power storage device 40 via the power conditioner 20, the emergency outlet 21, and the cable 41.

  Further, even when the power storage device 40 is being charged, if the switch of the load 50 is turned ON, the power charged in the power storage device 40 (from the power previously charged in normal time and from the power generation unit 10 in emergency) The supplied power) is supplied to the load 50 via the cable 43. It is to be noted that power is supplied only to the minimum necessary load (load 50) at the time of a power failure, and power is not supplied to the other loads 80.

  As described above, at the time of a power failure, the power from the power generation unit 10 can be charged to the power storage device 40 while the power from the power storage device 40 can be supplied to the load 50 at the same time. In this way, not only the power of the power storage device 40 is discharged, but also charging is performed in parallel, thereby efficiently loading the power previously charged in the power storage device 40 and the power newly generated in the power generation unit 10 into the load 50. Can be supplied to. Moreover, there is a concern about deterioration of the power storage device 40 (more specifically, a storage battery (lithium ion battery) in the power storage device 40) by simultaneously charging and discharging the power storage device 40 as described above. And discharging are performed only at the time of a power failure (emergency). Therefore, power can be efficiently supplied to the load 50 in an emergency while minimizing deterioration of the power storage device 40.

  Next, the configuration of the exhaust heat utilization system 200 of the power storage device 40 will be described with reference to FIGS. 3 to 6.

  The exhaust heat utilization system 200 of the power storage device 40 is a system that can utilize the exhaust heat of the power storage device 40. More specifically, the exhaust heat utilization system 200 of the power storage device 40 is a system for performing floor heating using the exhaust heat of the power storage device 40. In the present embodiment, the exhaust heat utilization system 200 is configured to perform floor heating of the living room 109. System. In addition to the power storage device 40, the exhaust heat utilization system 200 of the power storage device 40 mainly includes a hood 201, a fan 202, a first temperature sensor 203, a second temperature sensor 204, and a floor 205 (more specifically, Among the members constituting the floor portion 205, the hollow members 213, 213... And the heat storage materials 214, 214..., The upper opening / closing mechanism 206, the lower opening / closing mechanism 207, the exhaust port 208, and the control device 209. And composed of

  The hood 201 is for recovering the exhaust heat of the power storage device 40. The hood 201 is generally bowl-shaped with a space on the inside, and is formed so as to cover the periphery of the heat exhaust port (not shown) of the power storage device 40 from the outside. As a result, the exhaust heat of the power storage device 40 is discharged into the hood 201. When the exhaust heat of the power storage device 40 is discharged into the hood 201, the air in the hood 201 is warmed by the exhaust heat of the power storage device 40.

  The fan 202 is driven to supply the air in the hood 201 to the floor 205 (upstream opening 221 described later). The fan 202 is disposed in the hood 201.

  The first temperature sensor 203 detects the temperature in the hood 201. The first temperature sensor 203 is fixed to the side wall in the hood 201.

  The second temperature sensor 204 detects the temperature of the living room 109. The second temperature sensor 204 is fixed to the side wall of the living room 109.

  The floor portion 205 constitutes an indoor floor of the house 100. The floor portion 205 is formed by vertically superposing an upper floor panel 211 and a lower floor panel 212. In the present embodiment, the floor 205 has one side constituting the floor of the power storage device storage chamber 110, the other side constituting part of the floor of the deck 107, and the living room 109 between the one side and the other side. Make up the floor. That is, the floor portion 205 extends in the left-right (front-back) direction and is configured to straddle each room. And the floor part 205 which comprises the floor of the living 109 is comprised so that the floor heating of the living 109 can be performed.

  The lower floor panel 212 is mainly composed of joists 216, 216, floor materials 217, and heat insulating materials 218, 218,.

  The joists 216, 216,... Are a plurality of wooden members serving as the foundation of the floor portion 205. The joists 216, 216, ... are formed in a quadrangular prism shape. The joists 216, 216,... Are arranged side by side with a predetermined interval in the left-right direction, with the longitudinal direction being the front-rear direction (the direction perpendicular to the plane of FIG. 3). The joists 216, 216,... The large draw 401 is placed on a floor bundle 403 erected from the foundation 402.

  The flooring 217 is a member made of a particle boat, water-resistant plywood, or the like. The flooring 217 is formed in a flat plate shape. The flooring 217 is placed on the joists 216, 216, etc., and is fixed to the joists 216, 216, etc. using a fixture such as an adhesive or a nail.

  The heat insulating materials 218, 218... Prevent heat from flowing in and out of the room, and are members made of glass wool, urethane foam, or the like. The heat insulating materials 218, 218,... Are disposed below the floor material 217 and between the joists 216, 216,.

  The upper floor panel 211 is placed on the lower floor panel 212 and is fixed to the lower floor panel 212 using a fixture such as an adhesive or a nail. The upper floor panel 211 is mainly composed of hollow members 213, 213,..., A floor material 215, and heat storage materials 214, 214,.

  The hollow members 213, 213,... Are a plurality of members having a hollow structure and formed in a quadrangular prism shape. The upper floor panel 211 can reduce the weight of the upper floor panel 211 by using the hollow members 213, 213,... Having a hollow structure as one member constituting the upper floor panel 211.

  The hollow members 213, 213,... Are made of a material that is made of aluminum or resin, has excellent thermal conductivity, and has high rigidity. The hollow members 213, 213,... Are arranged side by side with a predetermined interval in the front-rear direction, with the longitudinal direction being the left-right direction. The hollow structure of the hollow members 213, 213... Extends in a direction parallel to the floor surface of the floor 205. More specifically, in the hollow structure of the hollow members 213, 213,..., A plurality of spaces are defined in the hollow members 213, 213, and the plurality of spaces are respectively in the longitudinal direction (left-right direction). It is formed by extending. With such a configuration, the hollow members 213, 213,... Are formed such that the front (left) end and the rear (right) end communicate with each other through the plurality of spaces.

  In the present embodiment, air (more specifically, air heated by exhaust heat of the power storage device 40) can pass between the front end and the rear end in the hollow members 213, 213. It is formed. The air passing through the hollow members 213, 213,... Serves as a heat source for storing heat in the heat storage materials 214, 214,. Moreover, the air which passes through the inside of hollow member 213 * 213 ... raises the temperature of the said hollow member 213 * 213 ... itself. And the hollow members 213, 213... Whose temperature has risen radiates heat to the living room 109 through the floor material 215, and performs floor heating of the living room 109.

  The floor material 215 is a finished surface of the floor portion 205 and is a member made of a wooden floor material, a carpet, or the like. The floor material 215 is formed in a flat plate shape. The floor material 215 is placed on the hollow members 213, 213... And fixed to the hollow members 213, 213.

  The heat storage materials 214, 214,... Are members that store heat and dissipate the stored heat, and are composed of a latent heat storage material or the like. The heat storage materials 214, 214,... Are disposed below the floor material 215 and between the adjacent hollow members 213, 213,. The heat storage materials 214, 214,... Are arranged in contact with the hollow members 213, 213, and the air passing through the hollow members 213, 213,. Heat exchange can be performed using air heated by heat as a heat source.

  In addition, the heat stored in the heat storage materials 214, 214... Is appropriately radiated. That is, the heat storage materials 214, 214... That store heat are radiated to the living room 109 through the floor material 215, and the floor 109 of the living room 109 is heated together with the hollow members 213, 213. It can be carried out. As described above, the floor heating is performed by using the heat storage materials 214, 214, etc. together with the hollow members 213, 213, etc., so that they are warmed by the exhaust heat of the power storage device 40 (released intermittently). Compared to the case where air is used for air conditioning for heating as it is, stable floor heating can be performed.

  Further, the floor 205 is formed with an upstream opening 221 and a downstream opening 222.

  The upstream opening 221 is provided in a portion of the floor 205 that forms the floor of the power storage device storage chamber 110. More specifically, the upstream opening 221 is provided so as to be located in the hood 201 in the power storage device storage chamber 110. The upstream opening 221 is a substantially rectangular shape in plan view, and is an opening formed through the floor 205 in the vertical direction. That is, the inside of the hood 201 of the power storage device storage chamber 110 and the lower portion of the floor portion 205 are configured to communicate with each other via the upstream opening 221. An upper opening / closing mechanism 206 and a lower opening / closing mechanism 207 are installed in the upstream opening 221.

  The downstream opening 222 is provided in a portion of the floor 205 that constitutes a part of the floor of the deck 107. The downstream opening 222 has a substantially rectangular shape elongated in plan view, and is formed by penetrating only the upper floor panel 211 in the vertical direction among the upper floor panel 211 and the lower floor panel 212 constituting the floor 205. (The lower floor panel 212 is not penetrated in the vertical direction). An exhaust port 208 is installed in the downstream opening 222.

  As described above, the inside of the hood 201 of the power storage device storage chamber 110 has two locations via the upstream opening 221, that is, below the floor 205, the hollow members 213, 213... And the downstream opening 222. It is comprised so that it may communicate with the deck 107 via.

  The upper opening / closing mechanism 206 partitions the inside of the hood 201 and the upstream opening 221 of the power storage device storage chamber 110 and communicates the inside of the hood 201 and the upstream opening 221 in a predetermined case. The upper opening / closing mechanism 206 is disposed so as to be substantially at the same position as the floor material 215 in the upper position of the upstream opening 221, more specifically in the vertical relationship. As shown in FIG. 6A, the upper opening / closing mechanism 206 is mainly composed of a first partition plate 232 and a second partition plate 231.

  Each of the first partition plate 232 and the second partition plate 231 is a plate-like member, and is formed of a material having high heat insulating properties. Through holes are formed in the first partition plate 232 and the second partition plate 231 at predetermined intervals. The upper opening / closing mechanism 206 is disposed in a state where the second partition plate 231 is overlapped from above the first partition plate 232. The second partition plate 231 is configured to be slidable relative to the first partition plate 232. The second partition plate 231 can be slid by an upper actuator 233 such as a motor or an air cylinder.

As shown in FIG. 6B, normally, in the state where the first partition plate 232 and the second partition plate 231 are overlapped, the through holes formed in the first partition plate 232 and the second partition plate 231 are Since there is no overlap in plan view, the upper opening / closing mechanism 206 (the first partition plate 232 and the second partition plate 231) partitions the inside of the hood 201 of the power storage device storage chamber 110 from the upstream opening 221 (upper opening / closing). Mechanism 206 is closed).
As shown in FIG. 6C, when the upper actuator 233 is driven and the second partition plate 231 is slid in one direction, the through hole of the first partition plate 232 and the through hole of the second partition plate 231 are formed. Overlapping in plan view, the inside of the hood 201 of the power storage device storage chamber 110 communicates with the upstream opening 221 (the upper opening / closing mechanism 206 is opened).

  The lower opening / closing mechanism 207 partitions the upstream opening 221 and the lower part of the floor 205, and communicates the upstream opening 221 and the lower part of the floor 205 in a predetermined case. The lower opening / closing mechanism 207 is disposed at the lower position of the upstream opening 221, more specifically, at the same position as the flooring 217 in the vertical relationship. As shown in FIG. 6A, the lower opening / closing mechanism 207 is formed with the same configuration as the upper opening / closing mechanism 206, and mainly includes a first partition plate 232 and a second partition plate 231. The

  Each of the first partition plate 232 and the second partition plate 231 is a plate-like member, and is formed of a material having high heat insulating properties. Through holes are formed in the first partition plate 232 and the second partition plate 231 at predetermined intervals. The lower opening / closing mechanism 207 is arranged in a state where the second partition plate 231 is overlapped from above the first partition plate 232. The second partition plate 231 is configured to be slidable relative to the first partition plate 232. The second partition plate 231 can be slid by a lower actuator 234 such as a motor or an air cylinder.

As shown in FIG. 6B, normally, in the state where the first partition plate 232 and the second partition plate 231 are overlapped, the through holes formed in the first partition plate 232 and the second partition plate 231 are Since there is no overlap in plan view, the lower opening / closing mechanism 207 (the first partition plate 232 and the second partition plate 231) partitions the upstream opening 221 and the lower part of the floor 205 (the lower opening / closing mechanism 207 is closed). ).
As shown in FIG. 6C, when the lower actuator 234 is driven and the second partition plate 231 is slid in one direction, the through hole of the first partition plate 232 and the through hole of the second partition plate 231 are formed. Overlapping in plan view, the upstream opening 221 communicates with the lower part of the floor 205 (the lower opening / closing mechanism 207 is opened).

  The exhaust port 208 partitions the downstream opening 222 and the deck 107 so that they can communicate with each other. The exhaust port 208 is disposed at the upper part of the downstream opening 222, more specifically, at the same position as the floor material 215 in the vertical position relationship. The exhaust port 208 is made of a plate-like member, and through-holes are formed at predetermined intervals.

The control device 209 controls driving of the upper actuator 233 of the upper opening / closing mechanism 206, the lower actuator 234 of the lower opening / closing mechanism 207, and the like based on various information. The control device 209 includes a storage unit such as a RAM and a ROM, an arithmetic processing unit such as a CPU, and the like.
The control device 209 is connected to the upper actuator 233 of the upper opening / closing mechanism 206 and can control the driving of the upper actuator 233 to open / close the upper opening / closing mechanism 206.
The control device 209 is connected to the lower actuator 234 of the lower opening / closing mechanism 207 and can control the driving of the lower actuator 234 to open / close the lower opening / closing mechanism 207.
The control device 209 is connected to the fan 202 and can control driving of the fan 202.
The control device 209 is connected to the first temperature sensor 203 and can acquire information related to the temperature in the hood 201 of the power storage device storage chamber 110.
The control device 209 is connected to the second temperature sensor 204 and can acquire information related to the temperature of the living room 109.

Next, the operation | movement aspect of the waste heat utilization system 200 of the electrical storage apparatus 40 is demonstrated using FIGS. 7-10.
7 to 10 indicate the flow of air in the hood 201 or the flow of air discharged from the hood 201. Moreover, the dashed-two dotted line arrow shown in FIG. 8 has shown the mode that the thermal radiation through the floor material 215, ie, floor heating, is performed.
The exhaust heat utilization system 200 of the power storage device 40 has three operation modes as described below.

  First, referring to FIG. 7, as a first operation mode of the exhaust heat utilization system 200, an operation when the power storage device 40 is not driven and the floor heating of the living room 109 using the exhaust heat of the power storage device 40 is not performed. An aspect is demonstrated.

  Hereinafter, the state of the exhaust heat utilization system 200 of the power storage device 40 in the above operation mode is referred to as a “first state”. In this first state, since the power storage device 40 is not driven, the power storage device 40 does not release exhaust heat.

  As shown in FIG. 7, in the first state, the fan 202 is not driven. Further, the upper actuator 233 of the upper opening / closing mechanism 206 is driven, and the upper opening / closing mechanism 206 is closed. Further, the lower actuator 234 of the lower opening / closing mechanism 207 is driven, and the lower opening / closing mechanism 207 is closed.

  As described above, in the first state, the inside of the hood 201 of the power storage device storage chamber 110 and the upstream opening 221 are partitioned by the upper opening / closing mechanism 206, and the inside of the hood 201 of the power storage device storage chamber 110 and the upstream opening are opened. The unit 221 is configured not to communicate. The upstream opening 221 and the lower part of the floor 205 are partitioned by the lower opening / closing mechanism 207 so that the upstream opening 221 and the lower part of the floor 205 do not communicate with each other.

  Accordingly, in the first state, the air in the hood 201 remains in the hood 201 and is not discharged outside the hood 201. Further, the hollow members 213, 213,... Are configured so that air does not pass through them. That is, the temperature of the hollow members 213, 213,... Does not rise, and the heat storage materials 214, 214,.

  Next, referring to FIGS. 8 and 9, as the second operation mode of the exhaust heat utilization system 200, the power storage device 40 is driven, and the floor 109 of the living room 109 is heated using the exhaust heat of the power storage device 40. An operation mode in the case of performing will be described.

  Hereinafter, the state of the exhaust heat utilization system 200 of the power storage device 40 in the above operation mode is referred to as a “second state”. In this second state, since the power storage device 40 is driven, the exhaust heat of the power storage device 40 is discharged into the hood 201.

  As shown in FIG. 8, in the second state, the fan 202 is driven. Further, the upper actuator 233 of the upper opening / closing mechanism 206 is driven, and the upper opening / closing mechanism 206 is opened. Further, the lower actuator 234 of the lower opening / closing mechanism 207 is driven, and the lower opening / closing mechanism 207 is closed.

  Thus, in the second state, the inside of the hood 201 of the power storage device storage chamber 110 and the upstream opening 221 are configured to communicate with each other by the upper opening / closing mechanism 206. The upstream opening 221 and the lower part of the floor 205 are partitioned by the lower opening / closing mechanism 207 so that the upstream opening 221 and the lower part of the floor 205 do not communicate with each other.

  Therefore, in the second state, the upper opening / closing mechanism 206 and the lower opening / closing mechanism 207 are configured so that the lower portion of the upstream opening 221 is “closed” and the hollow members 213, 213. Composed. That is, the air in the hood 201 (more specifically, the air heated by the exhaust heat of the power storage device 40) flows to the upstream opening 221 through the upper opening / closing mechanism 206 by driving the fan 202. And since the air which flowed to the upstream opening part 221 does not connect the upstream opening part 221 and the lower part of the floor part 205, it passes the inside of hollow member 213 * 213 ... downstream opening part 222. Flowing into. Then, the air that has flowed into the downstream opening 222 is discharged to the deck 107 through the exhaust port 208.

  Here, the air that passes through the hollow members 213, 213,... Is air that has been warmed by the exhaust heat of the power storage device 40 in the hood 201. Therefore, the said air raises the temperature of hollow member 213 * 213 ... itself. Further, heat exchange is performed between the air and the heat storage materials 214, 214,. That is, heat is stored in the heat storage materials 214, 214, ..., and the stored heat is radiated as appropriate. As a result, the hollow members 213 · 213 ··· and the heat storage materials 214 · 214 ··· can dissipate heat to the living room 109 via the floor material 215 and perform floor heating of the living room 109.

  The air that has passed through the hollow members 213, 213... Flows into the downstream opening 222 and is discharged to the deck 107 through the exhaust port 208. That is, the hollow members 213, 213,... Share the functions of the discharge path of the air heated by the exhaust heat of the power storage device 40 and the floor heating pipe. That is, with such a configuration, there is no need to provide a dedicated member (for example, an exhaust duct) for the air discharge path warmed by the exhaust heat of the power storage device 40, so that the installation cost can be reduced and the installation space can be made more efficient. Etc. can be achieved.

  In addition, the conditions for the operation | movement aspect of the exhaust heat utilization system 200 to be in a 2nd state may be preset to the control apparatus 209, or may respond to a resident's operation. Here, as an example of the conditions set in the control device 209 in advance, the power storage device 40 was driven, but the floor using the exhaust heat of the power storage device 40 because the initial temperature of the living room 109 was higher than the temperature in the hood 201. Heating was not performed (although it was in a third state to be described later), and then the temperature of the living room 109 became lower than the temperature in the hood 201, so floor heating was started using the exhaust heat of the power storage device 40. Cases are assumed.

  Next, referring to FIG. 10, as a third operation mode of the exhaust heat utilization system, when the power storage device 40 is driven and the floor 109 of the living room 109 is not heated using the exhaust heat of the power storage device 40. An operation mode will be described.

  Hereinafter, the state of the exhaust heat utilization system 200 of the power storage device 40 in the above operation mode is referred to as a “third state”. In this third state, since the power storage device 40 is driven, the exhaust heat of the power storage device 40 is discharged into the hood 201.

  As shown in FIG. 9, in the third state, the fan 202 is driven. Further, the upper actuator 233 of the upper opening / closing mechanism 206 is driven, and the upper opening / closing mechanism 206 is opened. Further, the lower actuator 234 of the lower opening / closing mechanism 207 is driven, and the lower opening / closing mechanism 207 is opened.

  Thus, in the third state, the upper opening / closing mechanism 206 communicates between the inside of the hood 201 of the power storage device storage chamber 110 and the upstream opening 221. Further, the lower opening / closing mechanism 207 communicates between the upstream opening 221 and the lower part of the floor 205.

  Therefore, in the third state, the air in the hood 201 (more specifically, the air warmed by the exhaust heat of the power storage device 40) is driven by the fan 202 to drive the upstream opening 221 via the upper opening / closing mechanism 206. Flowing into. The air flowing into the upstream opening 221 flows below the floor 205 via the lower opening / closing mechanism 207 because the upstream opening 221 communicates with the lower part of the floor 205. That is, since the air that has flowed from the inside of the hood 201 to the upstream opening 221 flows downward in the flow direction in the flow direction, the air does not pass through the hollow members 213, 213,. In other words, the upper opening / closing mechanism 206 and the lower opening / closing mechanism 207 are configured such that the lower portion of the upstream opening 221 is “open” and the hollow members 213, 213. As a result, the temperature of the hollow members 213, 213,... Does not rise, and the heat storage materials 214, 214,.

  Further, with such a configuration, even when the floor heating of the living room 109 using the exhaust heat of the power storage device 40 is not performed, the exhaust heat of the power storage device 40 is transferred from the power storage device storage chamber 110 (in the hood 201). It can be discharged below the floor 205. That is, it is possible to prevent the air in the power storage device storage chamber 110 (outside the hood 201) from being warmed by the exhaust heat of the power storage device 40, and consequently increase in the temperature of the power storage device 40.

  In addition, the conditions for the operation mode of the exhaust heat utilization system 200 to be in the third state may be set in the control device 209 in advance, or may be in accordance with a resident's operation. Here, as an example of conditions set in the control device 209 in advance, the power storage device 40 is driven to be in the second state. However, since the temperature of the living room 109 is higher than the temperature in the hood 201, The case where floor heating using waste heat is stopped is assumed.

Next, the configuration of the exhaust heat utilization system 300 of the power storage device 40 according to another embodiment of the present invention will be described with reference to FIGS. 11 and 12.
In addition, about the location of the structure same as the waste heat utilization system 200 of the electrical storage apparatus 40, the description is abbreviate | omitted suitably.

As shown in FIGS. 11 and 12, the location where the exhaust heat utilization system 300 of the power storage device 40 is different from the exhaust heat utilization system 200 is the air in which the exhaust heat utilization system 300 is heated by the exhaust heat of the power storage device 40. In addition to this, floor heating can be performed using other heat sources (hot water in this embodiment) (hot water floor heating can be performed). In addition to the members provided in the exhaust heat utilization system 200, the exhaust heat utilization system 300 of the power storage device 40 includes a warm water pipe 301 through which warm water as a heat source flows, a heat source unit 302 that heats the warm water by driving, The pump 303 is configured to supply hot water heated by the heat source device 302 to the hot water pipe 301.
In addition, in FIG.11 and FIG.12, arrangement | positioning with the hot water piping 301, the heat-source equipment 302, and the pump 303 is shown in image, and there is nothing which shows strictly the relationship with another member.

  One end of the hot water pipe 301 is connected to the pump 303, an intermediate part is formed by being appropriately bent, and the other end is connected to the pump 303 again. The middle part of the hot water pipe 301 is attached to the hollow members 213 213 formed in a hollow structure (more specifically, a plurality of spaces defined in the hollow members 213 213 213). . And the middle part of warm water piping 301 is formed so that it may reciprocate between the front-end | tip part and rear-end part of hollow member 213 * 213 ....

  With such a configuration, when the hot water heated by the heat source device 302 is supplied to the hot water pipe 301 by the pump 303, the temperature of the hollow members 213, 213,. Further, heat exchange is performed between the hot water passing through the hot water pipe 301 and the heat storage materials 214, 214,... Via the hollow members 213, 213,. That is, heat is stored in the heat storage materials 214, 214, ..., and the stored heat is radiated as appropriate. As a result, the hollow members 213, 213,... And the heat storage materials 214, 214, etc. can radiate heat to the living room 109 through the floor material 215 using hot water as a heat source, and perform floor heating of the living room 109. it can.

  Thus, in the exhaust heat utilization system 300 of the power storage device 40, in addition to the air heated by the exhaust heat of the power storage device 40, floor heating is performed using another heat source (hot water in the present another embodiment). (Hot water floor heating can be performed). In other words, in the exhaust heat utilization system 300 of the power storage device 40, air heated by the exhaust heat of the power storage device 40 and hot water heated by the heat source device 302 can be selected as the heat source for floor heating. Therefore, when only the hot water floor heating is performed in the normal time and the exhaust heat of the power storage device 40 can be used (when the power storage device 40 is driven), the exhaust heat of the power storage device 40 is combined with the hot water floor heating. Can be used for floor heating.

With such a configuration, for example, the air heated by the exhaust heat of the power storage device 40 is used as an auxiliary heat source for floor heating, so that the driving of the heat source device 302 when performing hot water floor heating is suppressed, and the heat source device 302 is driven. Electricity charges (or gas charges, etc.) can be reduced.
In the exhaust heat utilization system 300 of the power storage device 40, floor heating is performed using hot water heated by the heat source device 302 in addition to air heated by the exhaust heat of the power storage device 40. It is also possible to employ a configuration (electric floor heating) in which floor heating is performed using a heat source or the like as a heat source.

As described above, the exhaust heat utilization system 200 of the power storage device 40 is
A power storage device 40 capable of charging and discharging electric power used in a building (house 100);
A floor heating heat storage material (heat storage materials 214, 214...) Housed in the floor 205 of the building (living room 109);
A fan 202 for blowing air warmed by exhaust heat of the power storage device;
A ventilation portion for ventilating the air blown by the fan to the floor portion;
Comprising
The floor heating heat storage material stores heat using air passing through the ventilation portion as a heat source,
It is characterized by this.

  With such a configuration, the exhaust heat utilization system 200 of the power storage device 40 can use the exhaust heat of the power storage device 40 with a simple configuration. More specifically, the exhaust heat utilization system 200 of the power storage device 40 does not require complicated control (configuration) to use the exhaust heat of the power storage device 40 as in the related art, and the power storage device has a simple configuration. The floor heating can be performed using 40 exhaust heat.

Further, the exhaust heat utilization system 200 of the power storage device 40 includes:
A discharge part (lower part of the upstream opening 221) capable of discharging the air blown by the fan without passing through the ventilation part;
Open / close switching means (upper opening / closing mechanism 206 and lower opening / closing mechanism 207) for switching between opening and closing of the ventilation part and the discharge part,
Further comprising
When the floor heating heat storage material does not store heat, the opening / closing switching means switches the opening and closing of the ventilation section and the discharge section, and the air blown by the fan is discharged from the discharge section.
It is characterized by this.

  With such a configuration, the exhaust heat utilization system 200 of the power storage device 40 appropriately discharges the air heated by the exhaust heat of the power storage device 40 with a simple configuration when floor heating is not performed. It can prevent that the temperature of 40 becomes high.

Further, the exhaust heat utilization system 200 of the power storage device 40 includes:
First detection means (first temperature sensor 203) for detecting the temperature of the air heated by the exhaust heat of the power storage device;
Second detection means (second temperature sensor 204) for detecting the temperature of the indoor or outdoor air;
Control means (control device 209) for controlling switching of opening and closing of the ventilation part and the discharge part by the opening and closing switching means;
Further comprising
The control means controls switching between opening and closing of the ventilation part and the discharge part by the opening and closing switching means according to the detection result detected by the first detecting means and the second detecting means.
It is characterized by this.

  With such a configuration, the exhaust heat utilization system 200 of the power storage device 40 is set in the control device 209 in advance and the detection results of the first temperature sensor 203 and the second temperature sensor 204 without depending on the operation of the resident. Depending on the conditions, whether the floor heating is performed using the exhaust heat of the power storage device 40 or whether the air heated by the exhaust heat of the power storage device 40 is discharged without performing the floor heating is controlled with a simple configuration. be able to.

In the exhaust heat utilization system 200 of the power storage device 40,
The floor heating heat storage material is one member constituting hot water floor heating or electric floor heating,
It is characterized by this.

  With such a configuration, the exhaust heat utilization system 200 of the power storage device 40 uses hot air floor heating (or electric floor heating) by using the air heated by the exhaust heat of the power storage device 40 as an auxiliary heat source for floor heating. It is possible to suppress the driving of the heat source unit 302 when performing the operation, and thus to reduce the electricity bill (or gas fee, etc.) for driving the heat source unit 302.

In the exhaust heat utilization system 200 of the power storage device 40,
The floor portion includes a hollow member (hollow members 213, 213, ...) having a hollow structure extending in a direction parallel to the floor surface of the floor portion,
The vent is formed by the hollow member.
It is characterized by this.

  With such a configuration, the exhaust heat utilization system 200 of the power storage device 40 does not need to provide a dedicated member for the exhaust path of the air heated by the exhaust heat of the power storage device 40 such as an exhaust duct. The installation space can be made more efficient.

In the present embodiment, the exhaust heat utilization system 200 of the power storage device 40 is configured to perform floor heating of the living room 109 using the exhaust heat of the power storage device 40, but is configured to perform floor heating of another room. There may be.
In the present embodiment, the exhaust port 208 is provided in the deck 107, but the exhaust port 208 may be provided in another room, or may be provided outside the house 100 (outdoors).
The fan 202 is an embodiment of a “fan” according to the present invention, and the present invention is not limited to this. The “fan” according to the present invention is not configured to be provided outside the power storage device 40, for example, but is configured inside the power storage device 40, that is, exhaust heat of the power storage device 40 from the inside of the power storage device 40 through the heat exhaust port. It may be discharged.
The second temperature sensor 204 is an embodiment of the “second detection means” according to the present invention, and is not limited to this. The “second detecting means” according to the present invention may be configured to detect the temperature outside (outdoor) the house 100 instead of the living room 109, for example.
The upper opening / closing mechanism 206 and the lower opening / closing mechanism 207 are one embodiment of the “opening / closing switching means” according to the present invention, and the present invention is not limited to this. The "open / close switching means" according to the present invention may be configured to switch opening / closing of the lower portion of the upstream opening 221 and the hollow members 213, 213,.
Moreover, hollow member 213 * 213 ... is one Embodiment of the "hollow member" which concerns on this invention, and is not limited to this. Therefore, the number and shape of the plurality of spaces defined in the hollow members 213, 213,... Are not particularly limited.

40 Power storage device 100 Housing 109 Living 200 Waste heat utilization system 202 Fan 205 Floor portion 206 Upper opening / closing mechanism 207 Lower opening / closing mechanism 213 Hollow member 221 Upstream opening

Claims (5)

A power storage device capable of charging and discharging electric power used in buildings;
A floor heating heat storage material housed in the floor of the building;
A fan for blowing air heated by exhaust heat of the power storage device;
A ventilation portion for ventilating the air blown by the fan to the floor portion;
Comprising
The floor heating heat storage material stores heat using air passing through the ventilation portion as a heat source,
An exhaust heat utilization system for a power storage device. A discharge part capable of discharging the air blown by the fan without passing through the ventilation part;
Open / close switching means for switching open / close of the vent and the discharge part;
Further comprising
When the floor heating heat storage material does not store heat, the opening / closing switching means switches the opening and closing of the ventilation section and the discharge section, and the air blown by the fan is discharged from the discharge section.
The exhaust heat utilization system for a power storage device according to claim 1. First detection means for detecting the temperature of air heated by the exhaust heat of the power storage device;
Second detection means for detecting the temperature of the indoor or outdoor air;
Control means for controlling switching of opening and closing of the ventilation part and the discharge part by the opening and closing switching means;
Further comprising
The control means controls switching between opening and closing of the ventilation part and the discharge part by the opening and closing switching means according to the detection result detected by the first detecting means and the second detecting means.
The exhaust heat utilization system for a power storage device according to claim 1 or 2. The floor heating heat storage material is one member constituting hot water floor heating or electric floor heating,
The exhaust heat utilization system for a power storage device according to any one of claims 1 to 3, wherein the system is used. The floor portion includes a hollow member having a hollow structure extending in a direction parallel to the floor surface of the floor portion,
The vent is formed by the hollow member.
The exhaust heat utilization system for a power storage device according to any one of claims 1 to 4, wherein the system is used.

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