CN211503069U

CN211503069U - Suspension type fresh air purification and ventilation device with fresh air bypass function

Info

Publication number: CN211503069U
Application number: CN201922400238.4U
Authority: CN
Inventors: 陈文恭; 晏双涛
Original assignee: Beijing Huandu Top Air Conditioning Co ltd
Current assignee: Beijing Huandu Top Air Conditioning Co ltd
Priority date: 2019-12-27
Filing date: 2019-12-27
Publication date: 2020-09-15
Anticipated expiration: 2029-12-27

Abstract

The utility model discloses a ceiling type fresh air purifying and ventilating device with fresh air bypass function, which comprises a shell and a foaming component, wherein a heat exchanger and the foaming component are both detachably arranged in a hollow cavity of the shell and jointly divide the hollow cavity into an outdoor fresh air cavity, an indoor air return cavity, an indoor air supply cavity, an outdoor air discharge cavity and a bypass cavity; the outdoor fresh air cavity is communicated with the indoor air supply cavity through a heat exchanger, the indoor air return cavity is communicated with the outdoor air exhaust cavity through the heat exchanger, and two ends of the bypass cavity are respectively communicated with the indoor air return cavity and the outdoor air exhaust cavity. This suspension type new trend purifies breather has the new trend bypass function to can make partial new trend get into indoorly under the condition that does not pass through heat exchanger, make the room air be in the malleation state for a long time, be favorable to preventing that outdoor air that has not purified from getting into indoorly from other routes. And the assembling form of the internal structure modularization improves the assembling efficiency of products and the convenience of overhaul and maintenance.

Description

Suspension type fresh air purification and ventilation device with fresh air bypass function

Technical Field

The utility model belongs to new trend clarification plant field especially relates to a suspension type new trend purification breather with new trend bypass function.

Background

In hot summer or cold winter, people need to close doors and windows for a long time in order to keep a comfortable indoor air state; this causes carbon dioxide and dirty air to accumulate in the room, and the long-term exposure to such an environment may cause damage to the human body. The fresh air purifying and ventilating device is a ventilating device, and can provide fresh and comfortable air for a user under the condition of ensuring the tight closing of doors and windows.

At present, similar products in the market are more and more miscellaneous, and the products are mainly divided into: one-way air interchanger (only air intake and not air exhaust) and two-way air interchanger (air intake and air exhaust, and generally equipped with heat exchanger parts); a ventilator equipped with a high efficiency filter, and a ventilator not equipped with a high efficiency filter. According to the difference of mounting means, fresh air purification breather divide into again: ceiling mounted ventilators, floor mounted ventilators, wall mounted ventilators, and the like. The device is a product which is provided with a high-efficiency filter in a suspended ceiling type bidirectional flow mode.

The fresh air purifying and ventilating device of the ceiling type bidirectional flow preparation high-efficiency filter has many advantages: the ceiling type installation can realize the multi-purpose of one machine, and one device can be installed to process the air of different rooms simultaneously; the bidirectional flow product can exhaust indoor dirty air while supplying air to the indoor, so that quick air exchange is realized, and meanwhile, because the heat exchanger component is arranged in the device, the temperature and humidity energy in the exhaust air can be recycled to act on fresh air, so that the energy loss is effectively reduced; the device provided with the high-efficiency filter can remove harmful tiny particulate matters (PM2.5 particles and the like) in the air while ensuring the freshness of fresh air. However, because of the various functions of the device, the structure of the fresh air purifying and ventilating device with the suspension type bidirectional flow high-efficiency filter is relatively complex, and the manufacture, assembly, installation and maintenance of the device are difficult.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a modified suspension type fresh air purification breather with new trend bypass function is provided.

In order to realize the technical purpose, the utility model adopts the following technical scheme:

the utility model provides a suspension type fresh air purification breather with new trend bypass function, includes:

a housing having a hollow cavity;

the heat exchanger and the foaming component are both detachably arranged in a hollow cavity of the shell and jointly divide the hollow cavity into an outdoor fresh air cavity, an indoor air return cavity, an indoor air supply cavity, an outdoor air discharge cavity and a bypass cavity; the outdoor fresh air cavity is communicated with the indoor air supply cavity through a heat exchanger, the indoor air return cavity is communicated with the outdoor air exhaust cavity through the heat exchanger, one end of the bypass cavity is communicated with the outdoor fresh air cavity, and the other end of the bypass cavity is communicated with the indoor air supply cavity.

Preferably, the foaming component comprises fresh air inlet foaming, air exhaust inlet foaming, fresh air outlet foaming, air exhaust outlet foaming and bypass foaming; the fresh air inlet foaming and the air exhaust inlet foaming are oppositely arranged on two sides of the heat exchanger, and the fresh air outlet foaming and the air exhaust outlet foaming are oppositely arranged on two sides of the heat exchanger; the bypass foaming is arranged between the side wall of one side of the heat exchanger and the shell and is positioned between the fresh air inlet foaming and the air exhaust inlet foaming; the fresh air inlet foaming, the air exhaust inlet foaming, the fresh air outlet foaming, the air exhaust outlet foaming and the bypass foaming are all integrally formed by EPS foaming materials.

Wherein, the shell is provided with a fresh air inlet, an air exhaust inlet, a fresh air outlet and an air exhaust outlet; the fresh air inlet is foamed with a fresh air inlet channel, the exhaust air inlet is foamed with an exhaust air inlet channel, the exhaust air outlet is foamed with an exhaust air outlet channel, the fresh air outlet is foamed with a fresh air outlet channel, and the bypass foam is provided with a bypass channel;

the fresh air inlet is communicated with an outdoor fresh air cavity through the fresh air inlet channel, the exhaust inlet is communicated with an indoor return air cavity through the exhaust inlet channel, the fresh air outlet is communicated with an indoor air supply cavity through the fresh air outlet channel, the exhaust outlet is communicated with an outdoor exhaust cavity through the exhaust outlet channel, one end of the bypass channel is communicated with the fresh air inlet channel, and the other end of the bypass channel is communicated with the indoor air supply cavity;

the heat exchanger is provided with a first inlet, a second inlet, a first outlet and a second outlet, the first inlet is communicated with the fresh air inlet channel, the second inlet is communicated with the air exhaust inlet channel, the first outlet is communicated with the fresh air outlet channel, and the second outlet is communicated with the air exhaust outlet channel.

Preferably, the fresh air inlet channel is provided with an air inlet facing the fresh air inlet and an air outlet facing the first inlet of the heat exchanger, and the fresh air inlet channel is also provided with a bypass inlet facing the bypass foaming;

the air exhaust and intake passage has an air inlet facing the air exhaust inlet and an air outlet facing the second inlet of the heat exchanger;

the fresh air outlet channel is provided with an air inlet facing the first outlet of the heat exchanger and an air outlet facing the fresh air outlet;

the air exhaust outlet channel is provided with an air inlet facing the second outlet of the heat exchanger and an air outlet facing the air exhaust outlet;

the bypass channel is provided with an inlet facing the bypass inlet of the fresh air inlet channel and an air outlet facing the indoor air supply cavity.

Wherein preferably, the air exhaust inlet is foamed and the top plate defines a space above the air inlet from the first outlet of the heat exchanger to the fresh air outlet channel; the space above the air inlet from the second outlet of the heat exchanger to the air exhaust outlet channel is limited between the foaming of the fresh air inlet and the top plate;

the first inlet of the heat exchanger, the bottom plate of the shell and the side shell of the exhaust air outlet close to the heat exchanger together define an outdoor fresh air cavity from the outlet of the fresh air inlet channel to the first inlet of the heat exchanger; the second inlet of the heat exchanger, the bottom plate of the shell and the side shell of the fresh air outlet close to the heat exchanger define an indoor air return cavity from the outlet of the air exhaust and inlet channel to the second inlet of the heat exchanger; the first outlet of the heat exchanger, the top plate of the casing and the foamed top casing of the air exhaust inlet together define an indoor air supply cavity which flows from the first outlet of the heat exchanger to the fresh air supply channel through the foamed upper space of the air exhaust inlet; the second outlet of the heat exchanger, the top plate of the casing and the foamed top casing of the fresh air inlet together define an outdoor air exhaust cavity which flows from the second outlet of the heat exchanger through the space above the foamed fresh air inlet to the air exhaust outlet channel.

Preferably, the fresh air purifying and ventilating device further comprises a bypass valve, the bypass valve is arranged in the outdoor fresh air cavity and can swing back and forth along a set direction, the bypass valve swings to a first position, an air outlet of the fresh air inlet channel is closed, and a bypass inlet of the fresh air inlet channel is opened; when the bypass valve swings to a second position, the air outlet of the fresh air inlet channel is opened, and the bypass inlet of the fresh air inlet channel is closed; the bypass valve swings to any position between the first position and the second position, and the air outlet and the bypass inlet of the fresh air inlet channel are both opened.

Preferably, the bypass valve comprises a baffle plate, a connecting rod and a driving device, the baffle plate is connected with the driving device through the connecting rod, and the driving device can drive the baffle plate to swing back and forth along a set angle so as to seal an air outlet or a bypass inlet of the fresh air inlet channel.

Preferably, the heat exchanger is in a cuboid shape, a first edge of the heat exchanger is opposite to a second edge, and a third edge of the heat exchanger is opposite to a fourth edge;

the first edge and the second edge are respectively matched with the inner wall of the shell; the third edge is matched with the fresh air inlet foaming and the exhaust air outlet foaming, and the fourth edge is matched with the exhaust air inlet foaming and the fresh air outlet foaming;

a first bending part for limiting the third edge is formed on the side wall, close to the heat exchanger, of the fresh air inlet foaming part and the exhaust air outlet foaming part; and a second bending part used for limiting the fourth edge is formed on the side wall of the heat exchanger, close to the air exhaust inlet foaming and the fresh air outlet foaming.

Preferably, a first concave part is arranged on one side of the fresh air inlet foaming, which is close to the air exhaust outlet foaming, a first convex part is arranged on one side of the air exhaust outlet foaming, which is close to the fresh air inlet foaming, and the first convex part is clamped with the first concave part so as to fix the relative position of the fresh air inlet foaming and the air exhaust outlet foaming;

the side, close to the fresh air outlet, of the exhaust air inlet is provided with a second concave part, the side, close to the fresh air outlet, of the fresh air outlet is provided with a second convex part, and the second convex part is clamped with the second concave part to fix the relative positions of the exhaust air inlet and the fresh air outlet.

Preferably, a first fresh air filter is arranged between the fresh air inlet and the first inlet of the heat exchanger and between the fresh air inlet and the bypass channel;

and a second fresh air filter is arranged between the first outlet of the heat exchanger and the fresh air outlet and between the bypass channel and the fresh air outlet.

The utility model provides a suspension type fresh air purification breather with new trend bypass function, include the foaming subassembly by the foaming material preparation, it separates the cavity of shell for outdoor fresh air chamber jointly through heat exchanger and foaming subassembly, indoor return air chamber, indoor air supply chamber, outdoor air supply chamber and bypass chamber, wherein, the both ends of bypass chamber communicate with outdoor fresh air chamber and indoor air supply chamber respectively, it has the new trend bypass function to make this suspension type fresh air purification breather, thereby can make partial new trend get into under the condition that does not pass through heat exchanger indoor, make indoor air be in the malleation state for a long time, be favorable to discharging indoor dirty air, and prevent that outdoor air that does not purify from getting into from other routes indoor, can prevent outdoor dirty air's infiltration completely, to the effect preferred that keeps indoor high-quality air. And, above-mentioned foaming subassembly is by mould direct forming, will foam the subassembly during the equipment and put into the shell to carry out spacing the matching with heat exchanger and foaming subassembly, then other parts of repacking can, simultaneously, when needing the maintenance, directly will foam subassembly and each part and dismantle out from the shell can. The assembling form of the internal structure modularization greatly improves the assembling efficiency of products, reduces the labor cost, further improves the market competitiveness, and simultaneously improves the convenience of the maintenance of the whole device.

Drawings

Fig. 1 is a schematic top view of a ceiling type fresh air purifying and ventilating device according to an embodiment of the present invention;

fig. 2 is a schematic front view of a ceiling type fresh air purifying and ventilating device according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of the foaming assembly of FIG. 1;

FIG. 4 is a schematic view of another angle of the foaming component of FIG. 1;

FIGS. 5A and 5B are schematic structural diagrams of two views of the fresh air inlet foaming in FIG. 3;

FIG. 6 is a schematic view of the structure of the air inlet vent of FIG. 3;

FIG. 7 is a schematic structural view of the fresh air outlet of FIG. 3;

FIG. 8 is a schematic view of the structure of the discharge outlet of FIG. 3;

FIG. 9 is a schematic view of the bypass foaming of FIG. 3;

FIG. 10 is a schematic view of the bypass valve of FIG. 1.

In the drawings, each reference numeral denotes:

1. a housing; 11. an outdoor fresh air cavity; 12. an indoor air return cavity; 13. an indoor air supply cavity; 14. an outdoor exhaust cavity; 15. a bypass cavity; 16. a fresh air inlet; 17. an exhaust inlet; 18. a fresh air outlet; 19. an exhaust outlet;

2. a foaming component; 21. foaming at the fresh air inlet; 22. foaming at an exhaust inlet; 23. foaming at a fresh air outlet; 24. foaming at an exhaust outlet; 25. bypass foaming; 211. a fresh air inlet channel; 211A and an air outlet of the fresh air inlet channel; 211B, a bypass inlet of the fresh air inlet channel; 212. a first recess; 221. an air exhaust and intake passage; 222. a second recess; 231. a fresh air outlet channel; 232. a second boss portion; 241. an air exhaust and outlet channel; 242. a first boss portion; 251. a bypass channel;

3. a heat exchanger; 31. a first inlet; 32. a second inlet; 33. a first outlet; 34. a second outlet; 35. a first edge; 36. a second edge; 37. a third edge; 38. a fourth edge;

4. a first fan;

5. a second fan;

6. a first fresh air filter;

7. a second fresh air filter;

8. an exhaust air filter;

9. a control device;

10. a bypass valve; 101. a baffle plate; 102. a connecting rod; 103. a drive device;

20. a first bent portion;

30. a second bent portion;

40. and (7) overhauling the cover plate.

Detailed Description

The technical solution of the present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings that is solely for the purpose of facilitating the description and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 to 4, an embodiment of the present invention provides a ceiling type fresh air purifying and ventilating device with a fresh air bypass function, including: the device comprises a metal shell 1, a foaming component 2, a heat exchanger 3, a first fan 4, a second fan 5, a first fresh air filter 6, a second fresh air filter 7, a vent air filter 8, a control device 9 and a bypass valve 10. The first fan 4, the second fan 5 and the bypass valve 10 are all electrically connected with the control device 9, and the control device 9 can control the opening and closing of the first fan 4, the second fan 5 and the bypass valve 10, so that the operation and the stop of the whole device are controlled.

Referring to fig. 2 and 3, the metal housing 1 has a hollow inner cavity, and the housing 1 includes a top plate, a bottom plate, and four side walls, thereby defining a hollow cavity. Referring to fig. 1, the foaming component 2 and the heat exchanger 3 are both detachably mounted in a hollow cavity of the metal housing 1, and together divide the hollow cavity into an outdoor fresh air cavity 11, an indoor return air cavity 12, an indoor air supply cavity 13, an outdoor exhaust air cavity 14 and a bypass cavity 15.

Specifically, referring to the orientation of fig. 1, the heat exchanger 3 and the bypass chamber 15 are disposed at the middle of the metal casing 1, and the heat exchanger 3 and the bypass chamber 15 together divide the hollow cavity of the metal casing 1 into an indoor side and an outdoor side. The heat exchanger 3 has a first inlet 31, a second inlet 32, a first outlet 33, and a second outlet 34, the first inlet 31 communicating with the outdoor fresh air chamber 11, the second inlet 32 communicating with the indoor return air chamber 12, the first outlet 33 communicating with the indoor blowing air chamber 13, and the second outlet 34 communicating with the outdoor blowing air chamber 14.

The shell 1 is provided with a fresh air inlet 16, an exhaust air inlet 17, a fresh air outlet 18 and an exhaust air outlet 19. In this embodiment, the fresh air inlet 16, the exhaust air inlet 17, the fresh air outlet 18, and the exhaust air outlet 19 are disposed on both side wall plates of the casing 1 in a manner that the indoor side and the outdoor side are opposite to each other. The fresh air inlet 16 is communicated with the outdoor fresh air cavity 11, the exhaust air inlet 17 is communicated with the indoor return air cavity 12, the fresh air outlet 18 is communicated with the indoor air supply cavity 13, and the exhaust air outlet 19 is communicated with the outdoor exhaust air cavity 14. The outdoor fresh air cavity 11 is communicated with the indoor air supply cavity 13 through the heat exchanger 3, the indoor return air cavity 12 is communicated with the outdoor exhaust air cavity 14 through the heat exchanger 3, one end of the bypass cavity 15 is communicated with the outdoor fresh air cavity 11, and the other end of the bypass cavity 15 is communicated with the indoor air supply cavity 13.

The first fresh air filter 6 is arranged in the outdoor fresh air cavity 11 and is used for filtering larger particles (such as dust, lint and the like) in fresh air. At least a portion of the first fresh air filter 6 is located between the fresh air inlet 16 and the first inlet 31 of the heat exchanger 3, e.g., attached to the first inlet 31 of the heat exchanger 3; meanwhile, at least a part of the first fresh air filter 6 is located between the fresh air inlet 16 and the bypass cavity 15, for example, at the inlet of the bypass cavity 15, so as to ensure that the fresh air can be primarily filtered when entering the bypass cavity 15. The second fresh air filter 7 is arranged in the indoor air supply cavity 13 and is used for filtering micro harmful substances (such as PM2.5 particles) in fresh air. The second fresh air filter 7 is positioned between the first outlet 33 of the heat exchanger 3 and the fresh air outlet 18, and is attached to the first outlet 33 of the heat exchanger 3; meanwhile, the second fresh air filter 7 is located between the outlet of the bypass cavity 15 and the fresh air outlet 18, for example, located at the outlet of the bypass cavity 15, so as to ensure that the fresh air can be sent into the room after advanced filtration after coming out of the bypass cavity 15. The exhaust filter 8 is disposed in the indoor return air chamber 12 for filtering larger particles (e.g., dust, lint, etc.) in the indoor air, and the exhaust filter 8 may be attached to the second inlet 32 of the heat exchanger 3.

The first fan 4 is arranged in the indoor air supply cavity 13, an air outlet of the first fan 4 is communicated with indoor air through the fresh air outlet 18, and the fresh air inlet 16 is communicated with outdoor air. Outdoor fresh air can enter the outdoor fresh air cavity 11 through the fresh air inlet 16; the air enters the heat exchanger 3 for energy exchange after being primarily filtered by the first fresh air filter 6; the fresh air after energy exchange enters the indoor air supply cavity 13 after being subjected to advanced filtration by the second fresh air filter 7; the first fan 4 can send the fresh air which is filtered twice in the indoor air supply cavity 13 into the room, and the white arrow in fig. 1 indicates the flowing direction of the outdoor fresh air.

The second fan 5 is arranged in the outdoor air exhaust cavity 14, an air outlet of the second fan 5 is communicated with outdoor air through the air exhaust outlet 19, and the air exhaust inlet 17 is communicated with indoor air. Indoor air enters the indoor air return cavity 12 through the exhaust inlet 17, is subjected to primary filtration through the exhaust filter 8 and then enters the heat exchanger 3 for heat exchange; the air after heat exchange by the heat exchanger 3 enters the outdoor air discharging cavity 14, and the second fan 5 can discharge the air in the outdoor air discharging cavity 14 to the outdoor, where the black arrow in fig. 1 indicates the flowing direction of the indoor turbid air.

In this embodiment, utilize bypass cavity 15 can realize the new trend bypass function, and when the outdoor humiture is more suitable in spring and autumn, outdoor new trend can directly introduce to indoorly not passing through heat exchanger 3's energy exchange, can further reduce the loss of the energy like this, promotes heat exchanger 3's life simultaneously. It should be noted that although the outdoor fresh air does not pass through the heat exchanger 3, the outdoor fresh air is subjected to double filtration by the first fresh air filter 6 and the second fresh air filter 7, so that large particles and small particles (PM2.5 particles and the like) such as hairs and catkin in the air are filtered, and the quality of the fresh air is ensured.

The advantage of the fresh air bypass function lies in: the fresh air bypass function is that the outdoor air is directly sent into indoors after being purified, the indoor air can form positive pressure at the moment, the indoor air can seep out outdoors from door seams and window seams, outdoor polluted air is completely isolated, and the outdoor polluted air can be completely prevented from permeating. The cleanliness of the indoor air is ensured.

The principle that the fresh air bypass can form indoor positive pressure is as follows: when the fresh air bypass is opened, the outdoor fresh air not only passes through the heat exchanger channel but also can pass through the bypass channel, and the resistance of the fresh air channel is smaller than that of the exhaust channel, so that the air supply quantity is larger than the exhaust air quantity, and further, the indoor positive pressure is formed.

Furthermore, the embodiment of the utility model provides a suspension type fresh air purification breather, the foaming subassembly 2 that sets up in metal casing 1 is by mould direct forming. During the equipment will be foamed subassembly 2 and put into shell 1 to carry out spacing the matching with heat exchanger 3 and foamed subassembly 2, then other parts of repacking can, simultaneously, when needing the maintenance, directly with foamed subassembly 2 and each part follow shell 1 in dismantle out can. The assembling form of the internal structure modularization greatly improves the assembling efficiency of products, reduces the labor cost, further improves the market competitiveness, and simultaneously improves the convenience of the maintenance of the whole device.

In the above embodiment, preferably, as shown in fig. 3 and 4, the foaming component 2 includes a fresh air inlet foam 21, an exhaust air inlet foam 22, a fresh air outlet foam 23, an exhaust air outlet foam 24, and a bypass foam 25, and the fresh air inlet foam 21, the exhaust air inlet foam 22, the fresh air outlet foam 23, the exhaust air outlet foam 24, and the bypass foam 25 are all integrally formed by using an EPS foaming material. The fresh air inlet foaming 21, the exhaust air inlet foaming 22, the fresh air outlet foaming 23, the exhaust air outlet foaming 24, the bypass foaming 25 and the heat exchanger 3 are all detachably mounted in a hollow cavity of the metal shell 1, and the hollow cavity is divided into an outdoor fresh air cavity 11, an indoor air return cavity 12, an indoor air supply cavity 13, an outdoor exhaust air cavity 14 and a bypass cavity 15. The use of EPS for the production of foamed parts has the following advantages: firstly, the raw material cost is low, and the part forming and the die manufacturing are simple, so that the die opening cost and the manufacturing cost can be reduced; secondly, the EPS foaming quality is low, so that the whole device is light in weight and is more convenient to transport and install; thirdly, the EPS foam is softer, which is beneficial to improving the sealing performance of the whole device; fourthly, the sound and heat insulation effect of EPS foaming is better, and the heat preservation effect and the sound insulation effect of the whole device can be improved; fifthly, as the internal structure adopts an integral EPS foaming form, the foaming parts replace a sheet metal partition plate and a sealing element inside the metal sheet metal shell, and the assembly process of the product is further simplified; sixth, because set up EPS foaming part in the metal casing, the heat preservation effect of device is more excellent, has promoted the heat exchange efficiency of device, has reduced the possibility that the device produced the condensation, can make the device be suitable for more abominable environment to the cotton volume of heat preservation that the device need be used has been practiced thrift.

In the above embodiment, as shown in fig. 3 and 4, the fresh air inlet foam 21 and the exhaust air inlet foam 22 are oppositely disposed on two sides of the heat exchanger 3, and the fresh air outlet foam 23 and the exhaust air outlet foam 24 are oppositely disposed on two sides of the heat exchanger 3; the bypass foam 25 is arranged on the rear side wall of the heat exchanger 3 and is positioned between the fresh air inlet foam 21 and the exhaust air inlet foam 22. The fresh air direction and the return air direction in the fresh air channel and the return air channel are described with the lower side shown in fig. 1 as the front, that is, the surface facing to the front in fig. 2 as the front, and the upper side in fig. 2 as the upper side. In the plan view shown in fig. 1, the fresh air channel and the return air channel intersect in the direction from the rear right to the front left and in the direction from the rear left to the front right, and in the front view shown in fig. 2, the fresh air channel and the return air channel intersect in the direction from the lower right to the upper left and in the direction from the lower left to the upper right. In fig. 1 and 2, the white arrows indicate the flow direction of the fresh air, and the black arrows indicate the flow direction of the return air.

As shown in fig. 5 to 9, the fresh air inlet foam 21 has a fresh air inlet channel 211, the fresh air inlet channel 211 has an air inlet facing the fresh air inlet 16 and has an air outlet 211A facing the first inlet 31 of the heat exchanger 3, and the fresh air inlet channel 211 also has a bypass inlet 211B facing the bypass foam 25; the exhaust inlet foaming 22 has an exhaust air inlet channel 221, the exhaust air inlet channel 221 has an air inlet facing the exhaust inlet 17 and has an air outlet facing the second inlet 32 of the heat exchanger 3; the fresh air outlet foam 23 is provided with a fresh air outlet channel 231, and the fresh air outlet channel 231 is provided with an air inlet facing the first outlet 33 of the heat exchanger 3 and an air outlet facing the fresh air outlet 18; the exhaust outlet foaming 24 has an exhaust outlet channel 241, the exhaust outlet channel 241 has an air inlet facing the second outlet 34 of the heat exchanger 3 and has an air outlet facing the exhaust outlet 19; the bypass foam 25 has a bypass passage 251, and the bypass passage 251 has an inlet facing the bypass inlet 211B of the fresh air intake passage 211 and an outlet facing the indoor blowing chamber 13. The fresh air inlet 16 is communicated with the outdoor fresh air cavity 11 through the fresh air inlet channel 211, the exhaust air inlet 17 is communicated with the indoor return air cavity 12 through the exhaust air inlet channel 221, the fresh air outlet 18 is communicated with the indoor air supply cavity 13 through the fresh air outlet channel 231, the exhaust air outlet 19 is communicated with the outdoor air supply cavity 14 through the exhaust air outlet channel 241, one end of the bypass channel 251 is communicated with the bypass inlet 211B of the fresh air inlet channel 211, and the other end of the bypass channel 251 is communicated with the indoor air supply cavity 13.

The air exhaust inlet foaming 22 and the top plate define a space above the air inlet from the first outlet 33 of the heat exchanger 3 to the fresh air outlet channel 231; the fresh air inlet foam 21 and the top plate define a space above the second outlet 34 of the heat exchanger 3 to the inlet of the exhaust air outlet channel 241.

The heat exchanger 3 has a first inlet 31, a second inlet 32, a first outlet 33 and a second outlet 34, the first inlet 31 is communicated with the fresh air inlet channel 211 through an outdoor fresh air cavity 11, the second inlet 32 is communicated with the exhaust air inlet channel 221 through an indoor return air cavity 12, the first outlet 33 is communicated with the fresh air outlet channel 231 through an indoor air supply cavity 13, and the second outlet 34 is communicated with the exhaust air outlet channel 241 through an outdoor exhaust air cavity 14. Because each foaming part is mutually independent module, when conveniently installing and tearing open, can match according to the different foaming parts of the different sizes of the different choices of required cavity size to guarantee that the cavity of shell 1 can hold including all parts, the structure is comparatively compact moreover.

In the above embodiment, preferably, the fresh air purifying and ventilating device further includes a bypass valve 10. Referring to fig. 1, the bypass valve 10 is disposed in the outdoor fresh air chamber 11 and can be reciprocally swung in a set direction. When the bypass valve 10 swings to a first position (i.e., the position shown in fig. 1), the air outlet 211A of the fresh air intake channel 211 is closed, the bypass inlet 211B of the fresh air intake channel 211 is opened, and the bypass channel 251 is opened; at this time, the whole device is in a fresh air bypass mode, outdoor fresh air enters the bypass channel 251 after being filtered by the first fresh air filter 6, and then the fresh air subjected to primary filtration is discharged to the indoor from the fresh air outlet 18 after being filtered by the second fresh air filter 7 without passing through the energy exchange process of the heat exchanger 3. When the bypass valve 10 swings to a second position (needs to swing upwards in fig. 1), the air outlet 211A of the fresh air intake channel 211 is opened, the bypass inlet 211B of the fresh air intake channel 211 is closed, and the bypass channel 251 is closed; at the moment, the whole device is in a normal fresh air mode, outdoor fresh air enters the heat exchanger 3 through the fresh air inlet channel 211 for energy exchange, and is filtered twice and then is sent indoors. The bypass valve 10 swings to any position between the first position and the second position, the fresh air inlet channel 211 and the bypass channel 251 are both opened, and at the moment, the mixed fresh air mode is adopted, namely, part of outdoor fresh air passes through the heat exchanger 3 for heat exchange and is sent into the room after twice filtration, the other part of outdoor fresh air does not pass through the heat exchanger 3 and is directly sent into the room after twice filtration, and at the moment, the position of the bypass valve 10 can be adjusted to distribute air volume, so that the utilization rate of energy is improved.

In the above embodiment, preferably, as shown in fig. 10, the bypass valve 10 includes a baffle 101, a connecting rod 102 and a driving device 103, the baffle 101 is connected to the driving device 103 through the connecting rod 102, and the driving device 103 can drive the baffle 101 to swing back and forth along a set angle to close the air outlet 211A or the bypass inlet 211B of the fresh air intake channel 211, so as to control the opening and closing of the bypass channel 251. The bypass valve 10 in this embodiment is simple in structure and convenient to overhaul and maintain.

In the above embodiment, it is preferable that the heat exchanger 3 has a rectangular parallelepiped shape, and the first edge 35 of the heat exchanger 3 is opposite to the second edge 36, and the third edge 37 is opposite to the fourth edge 38. The first edge 35 and the second edge 36 are respectively matched with the inner walls of the top plate and the bottom plate of the shell 1, so that the hollow cavity is divided into an indoor side and an outdoor side; the third edge 37 is matched with the fresh air inlet foam 21 and the exhaust air outlet foam 24, and the fourth edge 38 is matched with the exhaust air inlet foam 22 and the fresh air outlet foam 23; the bypass foam 25 is arranged between the rear side wall of the heat exchanger 3 and the rear side wall of the shell 1 and is positioned between the fresh air inlet foam 21 and the exhaust air inlet foam 22. Four edges of the heat exchanger 3 are limited through the foaming parts and the inner wall of the shell 1 to fix the relative position of the heat exchanger 3, so that fresh air or indoor air can enter the heat exchanger 3 at the optimal angle for heat exchange.

In the above embodiment, preferably, the side walls of the fresh air inlet foam 21 and the exhaust air outlet foam 24 close to the heat exchanger 3 together form a first bending part 20 for limiting the third square edge 37; the side walls of the exhaust air inlet foam 22 and the fresh air outlet foam 23 close to the heat exchanger 3 are jointly formed with a second bending part 30 for limiting the fourth edge 38. Through the mode that first kink 20 and second kink 30 respectively with the third of heat exchanger 3, fourth edge assorted, when guaranteeing to carry on spacingly to heat exchanger 3, can also be right the edge of heat exchanger 3 plays certain guard action. The first bending part 20 and the second bending part 30 respectively form slide rails on two sides of the heat exchanger 3, when the heat exchanger is installed, the heat exchanger 3 is directly pushed to the position abutted against the bypass foaming 25 from one end of the first bending part 20 and the second bending part 30 close to the shell 1, and the installation is completed, so that the heat exchanger has the advantage of convenience in operation.

In the above structure, the first inlet 31 of the heat exchanger 3, the bottom plate of the casing 1 and the side casing of the discharge air outlet foaming 24 adjacent to the heat exchanger together define the outdoor fresh air chamber 11 from the outlet of the fresh air intake passage 211 to the first inlet 31 of the heat exchanger 3. The second inlet 32 of the heat exchanger 3, the bottom plate of the housing 1 and the side housing of the fresh air outlet foam 23 adjacent the heat exchanger together define an indoor return air chamber 12 from the outlet of the exhaust air intake channel 221 to the second inlet 32 of the heat exchanger 3. The first outlet 33 of the heat exchanger 3, the top plate of the housing 1 and the top housing of the discharge air inlet foam 22 together define an indoor plenum chamber 13 that flows from the first outlet 33 of the heat exchanger 3 through the space above the discharge air inlet foam 22 to the fresh air plenum 231. The second outlet 34 of the heat exchanger 3, the top plate of the housing 1 and the top housing of the fresh air inlet foam 21 together define an outdoor air discharge chamber 14 which flows from the second outlet 34 of the heat exchanger 3 through the space above the fresh air inlet foam 21 to the exhaust air outlet channel 241.

In the above embodiment, the fresh air entering from the fresh air inlet 16 is blown out from the air outlet of the fresh air inlet channel 211, enters the outdoor fresh air chamber 11 (located at the lower right corner as shown in fig. 2) communicated with the first inlet 31 of the heat exchanger 3, then flows through all the fresh air channels distributed along the entire lateral length direction of the heat exchanger 3, enters the indoor air supply chamber 13 (located at the upper left corner as shown in fig. 2) communicated with the first outlet 33 of the heat exchanger 3, is sucked into the fresh air outlet channel 231 by the first fan 4, and is finally sent to the indoor.

During heat exchange, outdoor return air entering from the exhaust inlet 17 is blown out from the air outlet of the exhaust air inlet channel 221, enters the indoor return air cavity 12 (located at the lower left corner shown in fig. 2) communicated with the second inlet 32 of the heat exchanger 3, then flows through all return air channels distributed along the whole lateral length direction of the heat exchanger 3, enters the outdoor exhaust air cavity 14 (located at the upper right corner shown in fig. 2) communicated with the second outlet 34 of the heat exchanger 3, is sucked into the exhaust air outlet channel 241 by the second fan 5, and is finally discharged to the outside.

When the bypass mode is turned on, outdoor fresh air entering from the fresh air inlet 16 flows through the bypass channel 251 from the bypass inlet 211B of the fresh air inlet channel 211, then enters an upper space defined between the top of the exhaust air inlet foam 22 and the top plate of the casing 1, is finally drawn into the fresh air outlet channel 231 by the first fan 4, and then is exhausted indoors.

In the above embodiment, preferably, a first concave portion 212 is provided on a side of the fresh air inlet foam 21 close to the exhaust air outlet foam 24, a first convex portion 242 is provided on a side of the exhaust air outlet foam 24 close to the fresh air inlet foam 21, and the first convex portion 242 is engaged with the first concave portion 212 to fix a relative position of the fresh air inlet foam 21 and the exhaust air outlet foam 24. Meanwhile, one side of the exhaust air inlet foam 22 close to the fresh air outlet foam 23 is provided with a second concave portion 222, one side of the fresh air outlet foam 23 close to the exhaust air inlet foam 22 is provided with a second convex portion 232, and the second convex portion 232 is clamped with the second concave portion 222 so as to fix the relative positions of the exhaust air inlet foam 22 and the fresh air outlet foam 23. Utilize bellying and depressed part complex mode can be earlier with each foaming spare part equipment location back, pack into the inner chamber of shell 1 again together, not only use comparatively convenient, need not additionally increase the connecting piece moreover. In addition, the connection of the fresh air outlet foaming 23 and the exhaust air inlet foaming 22 and the connection of the fresh air inlet foaming 21 and the exhaust air outlet foaming 24 are realized by matching the convex part and the concave part, and the sealing property of each cavity is also ensured.

Traditional suspension type fresh air purification breather needs to keep warm at the outside parcel heat preservation cotton of whole shell 1. In the embodiment, the fresh air inlet foam 21, the exhaust air inlet foam 22, the fresh air outlet foam 23, the exhaust air outlet foam 24 and the bypass foam 25 are all made of EPS materials, so that on one hand, a sheet metal baffle originally arranged inside a sheet metal shell is replaced, the structure inside the shell is simplified, and the assembly is more convenient; on the other hand, the heat insulating property and the sealing property of the whole device are improved, so that the whole device only needs a small amount of heat insulating cotton for heat insulation. Specifically, in the embodiment, only the heat preservation cotton needs to be adhered to the area, which is not covered by the EPS material, on the inner wall of the outdoor side of the shell 1, so that the heat preservation cotton is saved by 15%.

In the above embodiment, preferably, as shown in fig. 1, the casing 1 is further provided with an access opening, and the access opening is provided in a front wall plate of the casing corresponding to the heat exchanger 3. Ceiling type new trend purifies breather still includes access panel 40, access panel 40 detachably installs on the shell 1 to the shutoff access hole. When the whole device needs to be overhauled, the overhaul cover plate 40 is opened, and the whole device can be overhauled through the overhaul port. Simultaneously, because new trend import foaming 21, the import foaming 22 of airing exhaust, new trend export foaming 23, the export foaming 24 of airing exhaust and bypass foaming 25 are five independent modules, consequently, when overhauing, can tear out each module separately alone respectively, can greatly conveniently overhaul first fan 4, second fan 5, controlling means 9, and need not pull down whole device from the furred ceiling is inside, has greatly made things convenient for the maintenance work of product.

It is right above the utility model provides a suspension type fresh air purification breather with new trend bypass function has carried out detailed explanation. Any obvious modifications to the above would be obvious to those of ordinary skill in the art, without departing from the spirit of the present invention, and it is intended to constitute a violation of the patent rights of the present invention and to bear the relevant legal responsibility.

Claims

1. The utility model provides a suspension type fresh air purification breather with new trend bypass function which characterized in that includes:

a housing having a hollow cavity;

2. The ceiling type fresh air purifying and ventilating device according to claim 1, wherein:

the foaming component comprises fresh air inlet foaming, air exhaust inlet foaming, fresh air outlet foaming, air exhaust outlet foaming and bypass foaming; the fresh air inlet foaming and the air exhaust inlet foaming are oppositely arranged on two sides of the heat exchanger, and the fresh air outlet foaming and the air exhaust outlet foaming are oppositely arranged on two sides of the heat exchanger; the bypass foaming is arranged between the side wall of one side of the heat exchanger and the shell and is positioned between the fresh air inlet foaming and the air exhaust inlet foaming; the fresh air inlet foaming, the air exhaust inlet foaming, the fresh air outlet foaming, the air exhaust outlet foaming and the bypass foaming are all integrally formed by EPS foaming materials.

3. The ceiling type fresh air purifying and ventilating device according to claim 2, wherein:

the shell is provided with a fresh air inlet, an air exhaust inlet, a fresh air outlet and an air exhaust outlet; the fresh air inlet is foamed with a fresh air inlet channel, the exhaust air inlet is foamed with an exhaust air inlet channel, the exhaust air outlet is foamed with an exhaust air outlet channel, the fresh air outlet is foamed with a fresh air outlet channel, and the bypass foam is provided with a bypass channel;

4. The ceiling type fresh air purifying and ventilating device according to claim 3, wherein:

the fresh air inlet channel is provided with an air inlet facing the fresh air inlet and an air outlet facing the first inlet of the heat exchanger, and the fresh air inlet channel is also provided with a bypass inlet facing the bypass foaming;

5. The ceiling type fresh air purifying and ventilating device according to claim 4, wherein:

a space above the air inlet from the first outlet of the heat exchanger to the fresh air outlet channel is defined between the foaming of the air exhaust inlet and the top plate; the space above the air inlet from the second outlet of the heat exchanger to the air exhaust outlet channel is limited between the foaming of the fresh air inlet and the top plate;

6. The ceiling type fresh air purifying and ventilating device according to claim 4, wherein:

the fresh air purifying and ventilating device further comprises a bypass valve, the bypass valve is arranged in the outdoor fresh air cavity and can swing back and forth along a set direction, the bypass valve swings to a first position, an air outlet of the fresh air inlet channel is closed, and a bypass inlet of the fresh air inlet channel is opened; when the bypass valve swings to a second position, the air outlet of the fresh air inlet channel is opened, and the bypass inlet of the fresh air inlet channel is closed; the bypass valve swings to any position between the first position and the second position, and the air outlet and the bypass inlet of the fresh air inlet channel are both opened.

7. The ceiling type fresh air purifying and ventilating device as claimed in claim 6, wherein: the bypass valve comprises a baffle, a connecting rod and a driving device, the baffle is connected with the driving device through the connecting rod, and the driving device can drive the baffle to swing back and forth along a set angle so as to seal an air outlet or a bypass inlet of the fresh air inlet channel.

8. The ceiling type fresh air purifying and ventilating device according to claim 2, wherein:

the heat exchanger is in a cuboid shape, a first edge of the heat exchanger is opposite to a second edge, and a third edge of the heat exchanger is opposite to a fourth edge;

a first bending part for limiting the third edge is formed on the side wall, close to the heat exchanger, of the fresh air inlet foaming part and the exhaust air outlet foaming part;

and a second bending part used for limiting the fourth edge is formed on the side wall of the heat exchanger, close to the air exhaust inlet foaming and the fresh air outlet foaming.

9. The ceiling type fresh air purifying and ventilating device according to claim 2, wherein:

the side, close to the air exhaust outlet, of the fresh air inlet foam is provided with a first concave part, the side, close to the fresh air inlet foam, of the air exhaust outlet foam is provided with a first convex part, and the first convex part is clamped with the first concave part so as to fix the relative positions of the fresh air inlet foam and the air exhaust outlet foam;

10. The ceiling type fresh air purifying and ventilating device according to claim 3, wherein:

a first fresh air filter is arranged between the fresh air inlet and the first inlet of the heat exchanger and between the fresh air inlet and the bypass channel;