CN207555852U - A kind of underground heat exchange formula full heat recovery fresh air processing system - Google Patents

Abstract

The utility model discloses an underground heat exchange type total heat recovery fresh air treatment system, which includes a total heat exchanger, the total heat exchanger includes a box, and the outer wall of the box is provided with a first air inlet, a second air inlet, a first The air outlet, the second air outlet, the first fan and the second fan, the first bag filter, the total heat exchange core and the gas temperature controller connected in sequence are arranged inside the box, the inlet of the first bag filter The air outlet is connected to the air outlet of the first fan, the air inlet of the first fan is connected to the first air inlet, and the air outlet of the gas temperature controller is connected to the second air outlet; the first air inlet is also connected with a buried pipe fresh air treatment device, and the full heat exchanger is also connected with a power supply device. The utility model can make full use of the constant temperature characteristics of the soil layer, and then utilize the total heat exchange technology to recover the cold heat of the indoor return air, and combine the use of solar energy to reduce the energy consumption of fresh air treatment.

Description

An underground heat exchange type total heat recovery fresh air treatment system

technical field

The utility model belongs to the technical field of fresh air processing equipment, in particular to an underground heat exchange type full heat recovery fresh air processing system.

Background technique

Warm in winter and cool in summer, healthy and comfortable, is the housing concept that people are constantly pursuing. Generally, houses that consider energy-saving measures have better airtightness of the enclosure structure, which keeps the temperature and humidity inside the house at a relatively comfortable level. Due to the limited number of windows for ventilation and fresh air penetration, the indoor air quality is on a downward trend, and the gradual accumulation of smoke, dust, and VOC makes it necessary to consider the introduction of fresh air.

When the windows are opened for ventilation in summer, the thermal comfort satisfaction of the outdoor hot air entering the room is reduced, which will also increase the cooling load of the air conditioner in summer and increase the energy consumption of the air conditioner. In the same way, cold outdoor air enters the room during ventilation in winter, which also makes thermal comfort worse. If an air conditioner or a wall-hung boiler is used for heating, in order to ensure the original indoor thermal comfort, the energy consumption of the corresponding heating method will be increased, and when the outdoor air is slightly polluted or above, the indoor air quality is better than that of the outdoor.

Utility model content

The purpose of this utility model is to provide an underground heat exchange type full heat recovery fresh air treatment system, which can make full use of the constant temperature characteristics of the soil layer, and then use the full heat exchange technology to recover the cold heat of the indoor return air, and combine the use of solar energy to reduce the fresh air treatment energy. consumption.

The technical solution adopted by the utility model is: an underground heat exchange type total heat recovery fresh air treatment system, including a total heat exchanger, the total heat exchanger includes a box, and the outer wall of the box is provided with a first air inlet, a second The air inlet, the first air outlet, the second air outlet, the first fan and the second fan, the inside of the box is equipped with a first bag filter, a total heat exchange core and a gas temperature controller connected in sequence, the first bag The air inlet of the filter is connected with the air outlet of the first fan, the air inlet of the first fan is connected with the first air inlet, the air outlet of the gas temperature controller is connected with the second air outlet; the total heat exchange core is also connected with The second bag filter, the first bag filter and the second bag filter are respectively located on both sides adjacent to the total heat exchange core, the air inlet of the second bag filter is connected with the second air inlet, and the whole The heat exchange core is also connected to the second air outlet through the second fan;

The first air inlet is also externally connected with a buried pipe fresh air processing device, and the total heat exchanger is also connected with a power supply device.

The utility model is also characterized in that,

The buried pipe fresh air treatment device is a stainless steel pipe, and the inner wall of the stainless steel pipe is provided with an internal thread.

The power supply device includes a solar photovoltaic power generation device, an AC power distribution cabinet and a controller, and the solar photovoltaic power generation device and the controller are connected to the total heat exchanger through the AC power distribution cabinet.

The solar photovoltaic power generation device includes a solar cell square array, a battery pack, a charge and discharge controller, a grid-connected photovoltaic inverter and a voltage stabilizer connected in sequence, and the voltage stabilizer is connected to an AC power distribution cabinet.

The second air inlet is also externally connected with an electrostatic precipitator.

The gas temperature controller is a reheater or a surface cooler.

The beneficial effects of the utility model are:

(1) Make full use of the solar photovoltaic power generation system to provide electric energy for the total heat exchanger to support the normal operation of the fan, maximize the use of renewable energy, reduce the power consumption of the fan, make the fresh air system more energy-efficient, and reduce building energy consumption. Driven by the development trend of passive houses, this energy-saving fresh air system can also be widely popularized;

(2) Make full use of natural cold and heat sources, that is, use the constant temperature characteristics of the soil layer to cool and heat the outdoor fresh air, combined with the total heat exchange technology, can effectively and fully recover the cold and heat of the indoor exhaust air, so as to ensure the temperature and humidity of the indoor environment Constant, this solution can not only reduce the frequency of use of air conditioners, save energy and reduce consumption, but also improve indoor human comfort to meet air quality requirements and necessary fresh air requirements;

(3) This system is technically similar to ground source heat pumps but not the same. Compared with traditional ground source heat pumps, there is no need for expensive well drilling costs, no need to worry about technical failures, and the energy consumption of fans is higher than that of traditional fresh air treatment or air conditioning. It saves a lot of energy, and the full heat exchange technology is relatively mature, which can save users a lot of electricity bills;

(4) After the outdoor fresh air has been effectively treated, it can be re-purified by the electrostatic precipitator to ensure the cleanliness of the fresh air supplied to the room, reduce the number of windows for ventilation and obtain fresh air to improve the indoor air quality, thereby preventing indoor members from Respiratory or cardiovascular system discomfort caused by particulate pollutants brought in by fresh air.

Description of drawings

Fig. 1 is a structural schematic diagram of an underground heat exchange type total heat recovery fresh air treatment system of the present invention.

In the figure, 1. Cabinet, 2. Buried pipe fresh air treatment device, 3. AC power distribution cabinet, 4. Controller, 5. Solar photovoltaic power generation device, 6. Electrostatic precipitator;

1-1. The first air inlet, 1-2. The second air inlet, 1-3. The first air outlet, 1-4. The second air outlet, 1-5. The first fan, 1-6. The first Bag filter, 1-7. Full heat exchange core, 1-8. Gas temperature controller, 1-9. Second bag filter, 1-10. Second fan;

5-1. Solar battery array, 5-2. Battery pack, 5-3. Charge and discharge controller, 5-4. Grid-connected photovoltaic inverter, 5-5. Voltage stabilizer.

Detailed ways

The utility model will be described in detail below in conjunction with the accompanying drawings and specific embodiments.

The utility model provides an underground heat exchange type total heat recovery fresh air treatment system, as shown in Figure 1, including a total heat exchanger, the total heat exchanger includes a box body 1, and a first air inlet is provided on the outer wall of the box body 1 1-1, the second air inlet 1-2, the first air outlet 1-3, the second air outlet 1-4, the first fan 1-5 and the second fan 1-10, the inside of the box 1 is connected in sequence The first bag filter 1-6, the total heat exchange core 1-7 and the gas temperature controller 1-8, the air inlet of the first bag filter 1-6 and the air outlet of the first fan 1-5 connection, the air inlet of the first fan 1-5 is connected with the first air inlet 1-1, and the air outlet of the gas temperature controller 1-8 is connected with the second air outlet 1-4; the total heat exchange core 1-7 also A second bag filter 1-9 is connected, the first bag filter 1-6 and the second bag filter 1-9 are respectively located on both sides adjacent to the total heat exchange core 1-7, and the second bag filter The air inlet of the filter 1-9 is connected to the second air inlet 1-2, and the total heat exchange core 1-7 is also connected to the second air outlet 1-4 through the second fan 1-10;

The first air inlet 1-1 is also externally connected with a buried pipe fresh air processing device 2, and the total heat exchanger is also connected with a power supply device.

The buried pipe fresh air treatment device 2 is a stainless steel pipe, and the inner wall of the stainless steel pipe is provided with internal threads.

The power supply device includes a solar photovoltaic power generation device 5 , an AC power distribution cabinet 3 and a controller 4 , and the solar photovoltaic power generation device 5 and the controller 4 are connected to the total heat exchanger through the AC power distribution cabinet 3 .

The solar photovoltaic power generation device 5 includes a solar cell square array 5-1, a storage battery pack 5-2, a charging and discharging controller 5-3, a grid-connected photovoltaic inverter 5-4, and a voltage stabilizer 5-5 connected in sequence. The device 5-5 is connected with the AC power distribution cabinet 3.

The second air inlet 1-2 is also externally connected with an electrostatic precipitator 6 .

Gas temperature controllers 1-8 are reheaters or surface coolers.

The underground heat exchange type total heat recovery fresh air treatment system consists of three parts, namely the buried pipe fresh air treatment device 2, the total heat exchanger and the power supply device.

Buried pipe fresh air treatment device 2: Due to the negative pressure formed by the first fan 1-5, the outdoor fresh air enters the buried pipe from the air inlet. The buried pipe is made of stainless steel and equipped with a spiral internal thread. When the pipe is buried underground, the fresh air exchanges heat with the soil layer through the pipe wall. In summer, the outdoor temperature is higher than the soil layer, and the heat of the fresh air is transferred to the soil layer through the pipe wall. In winter, the outdoor fresh air temperature is lower than the soil layer. When the fresh air flows through the pipe, the soil The heat of the layer is transferred to the fresh air through the pipe wall, and the fresh air is heated. Due to the helical internal thread in the pipe, the fresh air will disturb the air flow when it flows through, which can effectively reduce the thickness of the heat exchange boundary layer and improve the effect of cold and heat exchange.

Total heat exchanger: After the fresh air enters through the buried pipeline, it first passes through the first bag filter 1-6 to filter visible impurities and most suspended particles, and then passes through the total heat exchange core and the indoor return air for heat and humidity transfer. After passing through the reheater or surface cooler, it is supplied to the indoor environment. If the outdoor air quality is at or below the level of light pollution, the occupants can manually turn on the electrostatic precipitator 6 in the fresh air duct to repurify the fresh air and then supply it indoors surroundings. Indoor dirty air passes through the indoor air outlet, after being filtered by the first bag filter 1-6, after full heat exchange with the fresh air, it is discharged into the outside by the fan. Return air is provided with the second bag filter 1-9 for avoiding indoor dust sources from polluting the total heat exchanger core 1-7 and avoiding performance degradation. The reheater or surface cooler is set up to meet the indoor air temperature and humidity requirements to meet human comfort. The setting of the electrostatic precipitator 6 is to ensure that when the outdoor air quality is not optimistic and the filter device installed in the total heat exchanger cannot meet the quality standard, the electrostatic precipitator 6 is turned on to re-purify the fresh air, so as to ensure the quality of the fresh air supplied to the room and reduce Airborne particulate matter is harmful to human health.

Power supply device: The solar cell installed on the roof or the top of the building is a device that directly converts solar energy into electrical energy based on the photovoltaic effect. It is essentially a semiconductor photodiode. When sunlight shines on the photodiode, on the semiconductor p-n junction, Form a new pair of holes and electrons. Under the action of the built-in electric field of the p-n junction, the holes flow from the n region to the p region, and the electrons flow from the p region to the n region. After the circuit is turned on, the photodiode will convert solar energy into electrical energy. current. When many batteries are connected in series or in parallel, it can become a solar cell square array 5-1 with relatively large output power. The current generated by the solar cell array 5-1 is imported and stored in the storage battery pack 5-2. Since the cycle charge and discharge times and the discharge depth of the battery are important factors determining the service life of the battery, it is necessary to connect and use the charge and discharge controller 5-3. A device that can automatically prevent the battery from overcharging and over-discharging. After the DC power is input to the grid-connected photovoltaic inverter 5-4, the output AC power needs to be stabilized by the voltage stabilizer 5-5, and then the AC power distribution cabinet 3 is used to provide power for the total heat exchanger. At night or in continuous rainy weather, when the power of the battery pack 5-2 is too low, the charging and discharging controller 5-3 sends the feedback signal to the controller and disconnects the DC-AC conversion circuit in order to prevent the battery from being over-discharged, and the controller 4 obtains After the signal, the mains path is opened, and the mains is sent to the full heat exchanger through the line through the AC power distribution cabinet 3 to make it work normally.

The utility model has the following advantages:

(1) Make full use of the solar photovoltaic power generation system to provide electric energy for the total heat exchanger to support the normal operation of the fan, maximize the use of renewable energy, reduce the power consumption of the fan, make the fresh air system more energy-efficient, and reduce building energy consumption. Driven by the development trend of passive houses, this energy-saving fresh air system can also be widely popularized;

(2) Make full use of natural cold and heat sources, that is, use the constant temperature characteristics of the soil layer to cool and heat the outdoor fresh air, combined with the total heat exchange technology, can effectively and fully recover the cold and heat of the indoor exhaust air, so as to ensure the temperature and humidity of the indoor environment Constant, this solution can not only reduce the frequency of use of air conditioners, save energy and reduce consumption, but also improve indoor human comfort to meet air quality requirements and necessary fresh air requirements;

(3) This system is technically similar to ground source heat pumps but not the same. Compared with traditional ground source heat pumps, there is no need for expensive well drilling costs, no need to worry about technical failures, and the energy consumption of fans is higher than that of traditional fresh air treatment or air conditioning. It saves a lot of energy, and the full heat exchange technology is relatively mature, which can save users a lot of electricity bills;

(4) After the outdoor fresh air has been effectively treated, it can be re-purified by the electrostatic precipitator to ensure the cleanliness of the fresh air supplied to the room, reduce the number of windows for ventilation and obtain fresh air to improve the indoor air quality, thereby preventing indoor members from Respiratory or cardiovascular system discomfort caused by particulate pollutants brought in by fresh air.

Claims (6)

1. a kind of underground heat exchange formula full heat recovery fresh air processing system, which is characterized in that including total-heat exchanger, the full heat is handed over Parallel operation includes babinet (1), and babinet (1) outer wall is equipped with the first air inlet (1-1), the second air inlet (1-2), the first outlet air Mouth (1-3), the second air outlet (1-4), the first wind turbine (1-5) and the second wind turbine (1-10), the babinet (1) are internally provided with successively The first bag filter (1-6), Total heat exchange core (1-7) and the gas temperature controller (1-8) of connection, the first pocket type mistake The air inlet of filter (1-6) is connect with the gas outlet of the first wind turbine (1-5), the air inlet and first of first wind turbine (1-5) Air inlet (1-1) connects, and the air outlet of the gas temperature controller (1-8) is connect with the second air outlet (1-4)；The full heat It exchanges core (1-7) and is also associated with the second bag filter (1-9), first bag filter (1-6) and the second bag type filtering Device (1-9) is located at the adjacent both sides of Total heat exchange core (1-7) respectively, the air inlet of second bag filter (1-9) and the Two air inlets (1-2) connect, and the Total heat exchange core (1-7) is also connected by the second wind turbine (1-10) and the second air outlet (1-4) It connects；

First air inlet (1-1) is also circumscribed with underground pipe Fresh air handing device (2), and the total-heat exchanger is also associated with supplying Electric installation.

2. a kind of underground heat exchange formula full heat recovery fresh air processing system as described in claim 1, which is characterized in that described buried Pipe Fresh air handing device (2) is stainless steel tube, and the inner wall of stainless steel tube is equipped with internal thread.

A kind of 3. underground heat exchange formula full heat recovery fresh air processing system as claimed in claim 2, which is characterized in that the power supply Device includes solar energy photovoltaic generator (5), AC power distribution cabinet/AC distribution panel (3) and controller (4), the solar energy photovoltaic generator (5) and controller (4) is connect by AC power distribution cabinet/AC distribution panel (3) with total-heat exchanger.

A kind of 4. underground heat exchange formula full heat recovery fresh air processing system as claimed in claim 3, which is characterized in that the sun Energy photovoltaic power generation apparatus (5) includes sequentially connected solar cell array (5-1), accumulator group (5-2), charging-discharging controller (5-3), grid-connected photovoltaic inverter (5-4) and voltage-stablizer (5-5), the voltage-stablizer (5-5) connect with AC power distribution cabinet/AC distribution panel (3).

5. a kind of underground heat exchange formula full heat recovery fresh air processing system as claimed in claim 4, which is characterized in that described second Air inlet (1-2) is also circumscribed with electrostatic precipitator (6).

A kind of 6. underground heat exchange formula full heat recovery fresh air processing system as claimed in claim 5, which is characterized in that the gas Temperature controller (1-8) is reheater or surface cooler.