CN220892437U - High-efficiency energy-saving fresh air conditioner unit capable of reducing carbon emission - Google Patents

Abstract

The utility model relates to a high-efficiency energy-saving fresh air conditioner unit capable of reducing carbon emission, which comprises a shell, wherein a baffle plate for dividing an inner cavity into a first cavity and a second cavity is arranged in the shell; an integrated primary plate filter, a bipolar electrostatic dust filter, a first heat recovery heat pipe, a blower, a nano photon purifier, a surface cooler, a wet film and a first silencer are sequentially distributed in the first cavity; an exhaust fan, a second heat recovery heat pipe and a second silencer are sequentially distributed in the second cavity, and the second heat recovery heat pipe is communicated with the first heat recovery heat pipe. The utility model has the advantages that: through add first heat recovery heat pipe, second heat recovery heat pipe in first cavity and second cavity to through the intercommunication that first heat recovery heat pipe and second heat recovery heat pipe realize the purpose of heat exchange, do not need the action of adding extra part can, do not have extra power consumption promptly, can effectually reduce the energy consumption, reduce carbon emission.

Description

High-efficiency energy-saving fresh air conditioner unit capable of reducing carbon emission

Technical Field

The utility model relates to a fresh air conditioning unit, in particular to a high-efficiency energy-saving fresh air conditioning unit capable of reducing carbon emission.

Background

With the increasing global warming and environmental pollution, people have increasingly demanded fresh air machines and air conditioners, and many large places are provided with both the air conditioners and the fresh air machines, such as large places of banks, hospitals, supermarkets and the like, and the air quality requirements of the places on the internal space are relatively high. And along with the wider and wider application range of the fresh air conditioner unit, the requirements on the unit are higher and higher, the traditional fresh air conditioner unit has higher energy consumption, and the corresponding carbon emission is more, so that the fresh air conditioner unit is not beneficial to environmental protection.

In CN111023331a, a combined runner heat recovery fresh air conditioning unit is provided, which comprises a housing, an air return opening, an air outlet, a fresh air opening and an air supply opening are arranged on the housing, a group of mutually matched functional sections are arranged in the housing, and the combined runner heat recovery fresh air conditioning unit comprises: the device comprises a fresh air filter screen section, a high-efficiency rotating wheel section, a refrigeration and heating surface cooling section, a humidifier section, a silencing section, an air supply section, an air exhaust filter section, an air exhaust section, and a side ventilation valve arranged between the air exhaust filter section and the refrigeration and heating surface cooling section; each functional section is matched to form a fresh air heat recovery functional group, a fresh air heat recovery air conditioning functional group and an internal circulation functional group.

In the fresh air conditioning unit in the above patent, the heat of indoor and outdoor air is exchanged by additionally arranging the efficient rotating wheel, so that the overlarge loss of the heat of the discharged indoor air is avoided, the heat of the introduced fresh air is improved, and the energy-saving effect is achieved. However, since the efficient rotating wheel is newly added, the operation of the efficient rotating wheel is power-consuming, so that the energy consumption of the fresh air conditioning unit is increased, and the overall energy-saving effect is not very good.

Disclosure of utility model

The utility model aims to solve the technical problem of providing a high-efficiency energy-saving carbon emission-reducing fresh air conditioning unit capable of effectively reducing energy consumption and carbon emission.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the utility model provides a high-efficient energy-conserving new trend air conditioning unit that reduces carbon emission which innovation point lies in: comprising

The shell is internally provided with a ventilation cavity, the shell is internally provided with a partition plate for dividing the ventilation cavity into a first cavity and a second cavity, the second cavity is positioned at the upper part of the shell, the first cavity consists of a lower side section positioned below the second cavity and a side section positioned beside the second cavity, and two sides of the shell are also provided with an air inlet and an air outlet which are communicated with the first cavity, and an air return and an air outlet which are communicated with the second cavity;

an integrated primary plate filter, a bipolar electrostatic dust filter, a first heat recovery heat pipe, a blower, a nano photon purifier, a surface cooler, a wet film and a first silencer are sequentially distributed in the first cavity from the fresh air inlet to the air supply inlet;

the exhaust fan, the second heat recovery heat pipe and the second silencer are sequentially distributed in the second cavity from the exhaust port to the return air port, the second heat recovery heat pipe is located above the first heat recovery heat pipe, and the second heat recovery heat pipe is communicated with the first heat recovery heat pipe.

Further, the fresh air port is positioned at the lower part of one side of the shell, and the air outlet is positioned at the upper part of the other side of the shell.

Further, the first heat recovery heat pipe and the second heat recovery heat pipe are both fin structures.

Furthermore, the shell is provided with a plurality of access doors at the first cavity and the second cavity.

The utility model has the advantages that: according to the utility model, the first heat recovery heat pipe and the second heat recovery heat pipe are additionally arranged in the first cavity and the second cavity, and the purpose of heat exchange is realized through the communication of the first heat recovery heat pipe and the second heat recovery heat pipe, so that the actions of adding extra parts are not needed, namely, extra energy consumption is avoided, the energy consumption can be effectively reduced, the carbon emission is reduced, and in addition, the mode can be used for preheating or precooling air in advance during refrigeration or heating, the efficiency is improved, and the high efficiency is realized.

Through add the wet film at the rear side of surface cooler, carry out humidification to the air that the surface cooler handled, avoid the air that sends out from the supply-air outlet too dry, improve user's use comfort.

The nanometer photon purifier arranged at the rear side of the blower is used for sterilizing and purifying air, so that the quality of the air is improved, germs are prevented from being diffused into the whole place through the air conditioning unit when epidemic situations or other similar conditions occur, and the safety is improved.

The first heat recovery heat pipe and the second heat recovery heat pipe are of fin type structures, so that the contact area of air can be increased and the heat exchange efficiency can be improved when the air contacts with the first heat recovery heat pipe or the second heat recovery heat pipe.

The fresh air inlet and the air outlet are respectively designed on two sides of the shell, so that the distance between the fresh air inlet and the air outlet is increased, and the condition that the indoor air exhausted by the air outlet directly enters the air conditioning unit from the fresh air inlet to influence the quality of fresh air is avoided.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

Fig. 1 is a schematic diagram of a high-efficiency energy-saving fresh air conditioning unit capable of reducing carbon emission.

Fig. 2 is a top view of the efficient energy-saving carbon emission-reducing fresh air conditioning unit.

Detailed Description

The following examples will provide those skilled in the art with a more complete understanding of the present utility model and are not intended to limit the utility model to the embodiments described.

A kind of energy-efficient fresh air conditioner unit which reduces carbon emission as shown in figure 1, figure 2, including

The shell 1 is of a hollow cuboid structure, a ventilation cavity is formed in the shell 1, a partition 13 for dividing the ventilation cavity into a first cavity 11 and a second cavity 12 is further arranged in the shell 1, the second cavity 12 is located at the upper portion of the shell 1, the first cavity 11 is composed of a lower side section located below the second cavity 12 and a side section located beside the second cavity 12, and a fresh air inlet 14 and an air supply outlet 15 which are communicated with the first cavity, and an air return inlet 16 and an air exhaust outlet 17 which are communicated with the second cavity are further formed in two sides of the shell 1.

The fresh air port 14 and the air outlet 17 are both positioned on the same side in the width direction of the shell 1, the air return port 16 and the air supply port 15 are both positioned on the other side in the width direction of the shell 1, the fresh air port 14 is positioned at the lower part of one side in the long axis direction of the shell 1, the air outlet 17 is positioned at the upper part of the other side in the long axis direction of the shell 1, the fresh air port 14 and the air outlet 17 are respectively designed on two sides in the long axis direction of the shell 1, and the design of staggered distribution is controlled up and down, so that the distance between the fresh air port 14 and the air outlet 15 is increased, and the indoor air exhausted by the air outlet 15 is prevented from directly entering an air conditioning unit from the fresh air port 14, and the quality of fresh air fed into the air conditioning unit from the fresh air port 14 is influenced.

The integrated primary plate filter 2, the bipolar electrostatic dust collection filter 21, the first heat recovery heat pipe 22, the blower 23, the nano photon purifier 24, the surface cooler 25, the wet film 26 and the first silencer 27 are sequentially distributed in the first cavity 11 from the fresh air inlet 14 to the air supply inlet 15, the integrated primary plate filter 2, the bipolar electrostatic dust collection filter 21, the first heat recovery heat pipe 22, the blower 23, the nano photon purifier 24, the surface cooler 25 and the wet film 26 are all located in the lower side section of the first cavity 11, and the first silencer 27 is located in the side section of the first cavity 11. The nano photon purifier 24 arranged at the rear side of the blower 23 is used for sterilizing and purifying the air introduced from the fresh air port 14, so that the quality of the air is improved, germs are prevented from diffusing into the whole place through the air conditioning unit when epidemic situation or other similar situations occur, and the safety in the place is improved; by additionally providing the wet film 26 on the rear side of the surface air cooler 25, the air processed by the surface air cooler 25 is humidified, so that the air sent out from the air supply port 15 is prevented from being excessively dried, and the use comfort of a user is improved.

The exhaust fan 3, the second heat recovery heat pipe 31 and the second silencer 32 are sequentially distributed in the second cavity 13 from the exhaust port 17 to the return port 16, the second heat recovery heat pipe 32 is located above the first heat recovery heat pipe 22, and the second heat recovery heat pipe 32 passes through the partition 13 to be communicated with the first heat recovery heat pipe 22.

The first heat recovery heat pipe 22 and the second heat recovery heat pipe 32 are both fin-type structures. The fin type structure is adopted for the first heat recovery heat pipe 22 and the second heat recovery heat pipe 32, so that when the air contacts with the first heat recovery heat pipe 22 or the second heat recovery heat pipe 32, the contact area can be increased, and the heat energy exchange efficiency between the first heat recovery heat pipe 22 and the second heat recovery heat pipe 32 can be improved.

A plurality of access doors 4 are also arranged on the housing 1 at the first cavity 11 and the second cavity 12. Access doors 4 are arranged at different positions, so that personnel can conveniently enter the shell 1 to overhaul devices of the air conditioning unit.

Working principle: when the air supply is performed, firstly, external fresh air enters the first cavity 11 through the fresh air inlet 14, and is subjected to filtering treatment through the integrated primary plate filter 2 and the bipolar electrostatic dust removal filter 21 in sequence, the fresh air at the filtering opening is subjected to sterilization and purification through the first heat recovery heat pipe 22, the purified fresh air is subjected to refrigeration and refrigeration through the surface air cooler 25 and the wet film 26 through the nano photon purifier 24, and finally is subjected to silencing through the first silencer 27 and is sent into a place from the air supply outlet 15.

When the air is returned, indoor air in the place enters the second cavity 12 from the air return opening 116, is subjected to silencing through the second silencer 32, passes through the second heat recovery heat pipe 32, is subjected to pretreatment by utilizing heat exchange between the second heat recovery heat pipe 32 and the first heat recovery heat pipe 22, and is finally sent out of the place through the air outlet 17 by the air exhauster 3.

It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (4)

1. The utility model provides a high-efficient energy-conserving new trend air conditioning unit that reduces carbon emission which characterized in that: comprising

The shell is internally provided with a ventilation cavity, the shell is internally provided with a partition plate for dividing the ventilation cavity into a first cavity and a second cavity, the second cavity is positioned at the upper part of the shell, the first cavity consists of a lower side section positioned below the second cavity and a side section positioned beside the second cavity, and two sides of the shell are also provided with an air inlet and an air outlet which are communicated with the first cavity, and an air return and an air outlet which are communicated with the second cavity;

an integrated primary plate filter, a bipolar electrostatic dust filter, a first heat recovery heat pipe, a blower, a nano photon purifier, a surface cooler, a wet film and a first silencer are sequentially distributed in the first cavity from the fresh air inlet to the air supply inlet;

the exhaust fan, the second heat recovery heat pipe and the second silencer are sequentially distributed in the second cavity from the exhaust port to the return air port, the second heat recovery heat pipe is located above the first heat recovery heat pipe, and the second heat recovery heat pipe is communicated with the first heat recovery heat pipe.

2. The efficient energy-saving carbon emission-reducing fresh air conditioning unit according to claim 1, wherein: the fresh air port is positioned at the lower part of one side of the shell, and the air outlet is positioned at the upper part of the other side of the shell.

3. The efficient energy-saving carbon emission-reducing fresh air conditioning unit according to claim 1, wherein: the first heat recovery heat pipe and the second heat recovery heat pipe are of fin type structures.

4. The efficient energy-saving carbon emission-reducing fresh air conditioning unit according to claim 1, wherein: and a plurality of access doors are also arranged on the shell and positioned at the first cavity and the second cavity.