CN216592106U - New fan of self-balancing - Google Patents

Abstract

The utility model discloses a self-balancing fresh air machine, belonging to the field of fresh air machines and solving the problem that the drying agent and the aqueous medium need to be replaced regularly in the existing fresh air machine, which is complicated; this scheme includes admission line and exhaust duct, the admission line is provided with humidity transducer towards outdoor one end, the indoor one end of orientation is provided with dry component, dry component is used for carrying out drying process to outdoor air, be provided with the humidification component between admission line and the exhaust duct, the humidification component is used for providing atomizing aqueous medium and carries out aqueous medium to the air in the exhaust duct simultaneously and retrieve, it is higher when indoor humidity, when needing the drying, air humidity in the exhaust duct is higher, can be through the moisture in the air of humidification component in with the exhaust duct, also be that the water droplet peels off, loopback to the water tank in, greatly reduced injects new aqueous medium's time cycle in to the new fan.

Description

New fan of self-balancing

Technical Field

The utility model belongs to new fan field, concretely relates to new fan of self-balancing.

Background

The new fan is one kind and is used for changing the room air, make the more fresh equipment of room air, the new fan is inside generally to be provided with the drying, the humidification, the heating, remove dust, heat exchange and so on structure, a purification is carried out one time to outdoor air, processing such as dry humidity, send outdoor air indoor again, guarantee that indoor air circumstance is enough good, above-mentioned in-process, the drying generally utilizes the drier, the humidification generally utilizes the water atomization, wherein, long-time the use back, the inside moisture that is full of drier, drying performance obviously descends, need wait for its inside moisture evaporation or directly change the drier, the water medium atomizing has the consumption, need regularly add the water medium, it is all comparatively loaded down with trivial details, therefore, the utility model provides a self-balancing new fan.

SUMMERY OF THE UTILITY MODEL

In order to solve the above-mentioned among the background art, among the current new fan, need regularly change drier and aqueous medium, comparatively loaded down with trivial details problem, the utility model provides a new fan of self-balancing.

The purpose of the utility model can be realized by the following technical scheme:

the utility model provides a new fan of self-balancing, including admission line and exhaust duct, it trades the part to be provided with the heating between admission line and the exhaust duct, the admission line is provided with humidity transducer towards outdoor one end, indoor one end of orientation is provided with dry component, humidity transducer is used for responding to outdoor air's humidity and transmits the response result for dry component through the signal transmission mode, dry component is used for carrying out drying process to outdoor air, be provided with the humidification component between admission line and the exhaust duct, the humidification component is used for providing atomizing aqueous medium and carries out aqueous medium to the air in the exhaust duct simultaneously and retrieve.

Furthermore, the drying component comprises a casing, one end of the casing is open, the other end of the casing is closed, two side surfaces of the casing along the width direction of the casing are respectively provided with a connecting hole, one group of connecting holes are communicated with the air inlet pipeline, and the other group of connecting holes are communicated with the indoor space;

an inner plate is arranged in the casing in a sliding manner, and the inner plate is connected with the casing in a sliding manner through a guide piece;

the side surface of the inner plate along the width direction of the shell is provided with a drying hole, two orifices of the drying hole are both provided with a mesh enclosure, and a drying agent is arranged in the drying hole;

the side of the casing is provided with a magnet, the side of the inner plate is provided with an electromagnet, and the inner plate is driven to move close to the bottom of the casing cavity by the magnetic adsorption force between the electrification of the electromagnet and the magnet.

Furthermore, the guide piece comprises a guide rod, the guide direction of the guide rod is parallel to the extension direction of the casing, the guide rod is fixed with the inner plate, the guide rod is connected with the casing in a sliding mode, a spring is sleeved outside the guide rod, and the inner plate is driven by the compression elasticity of the spring to move away from the bottom of the cavity of the casing.

Furthermore, the air inlet pipeline is provided with a control valve a positioned between the heat exchange part and the drying component, and the air outlet pipeline is provided with a control valve b positioned on the outdoor side of the heat exchange part.

Further, the humidifying component comprises a water tank and an atomizer, and the atomizer is used for sucking the water medium in the water tank and atomizing the water medium;

the humidifying component further comprises a filtering pipeline, two ends of the filtering pipeline are communicated with the exhaust pipeline, the control valve b is located between two ends of the filtering pipeline, a cyclone separator is arranged on the filtering pipeline and used for receiving air in the exhaust pipeline and carrying out dust centrifugal treatment on the air, and a control valve c located on one side, facing the indoor side, of the cyclone separator is further arranged on the filtering pipeline.

Furthermore, the humidifying component also comprises a recovery pipeline, one end of the recovery pipeline is communicated with a discharge port of the cyclone separator, the other end of the recovery pipeline is connected with an atomizer, a connecting nozzle is arranged on the side surface of the water tank and is communicated with the recovery pipeline, and a control valve d close to the atomizer is arranged on the recovery pipeline;

a control valve e for communicating the atomizer and the air inlet pipeline is arranged between the atomizer and the air inlet pipeline, the control valve e is positioned between the heat exchange part and the control valve a, a humidifying pipeline is also arranged between the atomizer and the air inlet pipeline, one end of the humidifying pipeline is communicated with the atomizer, the other end of the humidifying pipeline is communicated with the humidifying pipeline, and the end of the humidifying pipeline is positioned between the drying component and the control valve a.

Compared with the prior art, the beneficial effects of the utility model are that:

according to the scheme, the air in the air inlet pipeline is dried through the drying component, and the air in the air inlet pipeline is humidified through the humidifying component;

in this scheme, indoor humidity is higher, when needing to be dry, can open control valve a, control valve c, close control valve b, control valve d, control valve e, and at this moment, the air among the exhaust duct passes through the filter tube, the cyclone is outdoor after the discharge, and this in-process, cyclone peels off the moisture in the air, also be exactly the water droplet, returns the water droplet to the water tank in through the recovery tube, greatly reduced injects new aqueous medium's time cycle into the new fan.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the description below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural view of the humidifying component of the present invention;

FIG. 3 is a schematic structural view of the drying member of the present invention;

fig. 4 is a cross-sectional view of the drying member of the present invention;

fig. 5 is a schematic structural diagram of the inner plate of the present invention.

Reference numerals:

10. an air intake duct; 11. a humidity sensor; 12. a control valve a; 20. an exhaust duct; 21. a control valve b; 30. a heat exchange member; 40. a drying member; 41. a housing; 42. connecting holes; 43. an inner plate; 44. a guide bar; 45. a spring; 46. a mesh enclosure; 47. an electromagnet; 48. a magnet; 50. a humidifying member; 51. a water tank; 52. a filtration pipeline; 53. a control valve c; 54. a cyclone separator; 55. a recovery pipeline; 56. an atomizer; 57. a control valve d; 58. a control valve e; 59. a humidifying conduit.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1, a self-balancing fresh air blower includes an air inlet duct 10 and an air outlet duct 20, wherein a humidity sensor 11 is disposed at an end of the air inlet duct 10 facing outdoors, a drying member 40 is disposed at an end facing indoors, the humidity sensor 11 is configured to sense humidity of outdoor air and transmit a sensing result to the drying member 40 in a signal transmission manner, and the drying member 40 is configured to dry the outdoor air.

A heat exchange component 30 is further disposed between the air inlet duct 10 and the air outlet duct 20, the heat exchange component 30 is used for exchanging heat of air between the air inlet duct 10 and the air outlet duct 20, and both the heat exchange component 30 and the humidity sensor 11 can be implemented in the prior art, which is not described in detail.

A humidifying component 50 is arranged between the air inlet pipeline 10 and the exhaust pipeline 20, and the humidifying component 50 is used for providing atomized aqueous medium for the air in the air inlet pipeline 10 and recovering the aqueous medium from the air in the exhaust pipeline 20, so that the time period of injecting new aqueous medium into the fresh air machine is greatly reduced.

As shown in fig. 3 to 5, the drying member 40 includes a casing 41, one end of the casing 41 is open, the other end is closed, and both side surfaces of the casing 41 in the width direction thereof are provided with connecting holes 42: one group is connected to the intake duct 10, and the other group is connected to the indoor space.

An inner plate 43 is slidably arranged in the sleeve 41, the inner plate 43 is slidably connected with the sleeve 41 through a guide, specifically, the guide comprises a guide rod 44, the guide direction of which is parallel to the extending direction of the sleeve 41, the guide rod 44 is fixed with the inner plate 43 and is slidably connected with the sleeve 41, a spring 45 is sleeved outside the guide rod 44, and the compression elastic force of the spring 45 drives the inner plate 43 to move away from the cavity bottom of the sleeve 41.

The inner plate 43 is provided with a drying hole along the side of the housing 41 in the width direction, both openings of the drying hole are provided with a mesh enclosure 46, and a drying agent is arranged in the drying hole.

The side of the sleeve 41 is provided with a magnet 48, the side of the inner plate 43 is provided with an electromagnet 47, and the inner plate 43 is driven to move close to the bottom of the cavity of the sleeve 41 by the magnetic attraction force between the electromagnet 47 and the magnet 48.

The operation of the drying member 40 is embodied as follows:

when the indoor humidity is high and dehumidification is needed, the inner plate 43 is driven to move close to the bottom of the cavity of the shell 41 by the magnetic adsorption force between the electromagnet 47 and the magnet 48, so that the drying hole is communicated with the connecting hole 42, and at the moment, air in the air inlet pipeline 10 passes through the drying agent in the drying hole before entering the indoor space, is dried by the drying agent and then flows into the indoor space;

when the indoor humidity is low and humidification is needed, the electromagnet 47 is powered off, the compression elasticity of the spring 45 drives the inner plate 43 to move away from the cavity bottom of the sleeve 41, so that the drying hole is separated from the connecting hole 42 and is blocked by the sleeve 41, and at the moment, the air in the air inlet pipeline 10 enters the indoor space directly through the connecting hole 42 after being humidified by the humidifying component 50.

As shown in fig. 2, the air inlet duct 10 is provided with a control valve a12 positioned between the heat exchange part 30 and the drying member 40, and the air outlet duct 20 is provided with a control valve b21 positioned at the outdoor side of the heat exchange part 30.

The humidifying component 50 includes a water tank 51 and an atomizer 56, and the atomizer 56 is used for sucking the water medium in the water tank 51 and performing atomization treatment on the water medium, which can be realized by the prior art and is not described in detail.

The humidifying component 50 further comprises a filtering pipeline 52, two ends of the filtering pipeline 52 are both communicated with the exhaust pipeline 20, the control valve b21 is located between the two ends of the filtering pipeline 52, a cyclone 54 is arranged on the filtering pipeline 52, the cyclone 54 is used for receiving the air in the exhaust pipeline 20 and performing dust centrifugal treatment on the air, and for the realization of the prior art, no description is given, the filtering pipeline 52 is further provided with a control valve c53 located on one indoor side of the cyclone 54.

The humidifying component 50 further comprises a recovery pipeline 55, one end of the recovery pipeline 55 is communicated with a discharge port of the cyclone 54, the other end of the recovery pipeline 55 is connected with an atomizer 56, a connecting nozzle is arranged on the side face of the water tank 51 and communicated with the recovery pipeline 55, and a control valve d57 close to the atomizer 56 is arranged on the recovery pipeline 55.

A control valve e58 for communication between the atomizer 56 and the air inlet duct 10 is provided between the atomizer 56 and the air inlet duct 10 and a control valve e58 is located between the heat exchange part 30 and the control valve a12, a humidification duct 59 is further provided between the atomizer 56 and the air inlet duct 10, one end of the humidification duct 59 is communicated with the atomizer 56, the other end is communicated with the humidification duct 59, and the end is located between the drying member 40 and the control valve a 12.

The working process of the humidifying component 50 specifically comprises the following steps:

when the indoor humidity is low and humidification is needed, the control valve a12 and the control valve b21 are closed, the control valve c53, the control valve d57 and the control valve e58 are opened, wherein the air in the exhaust pipeline 20 is exhausted to the outside after passing through the filtering pipeline 52 and the cyclone separator 54, in the process, the cyclone separator 54 strips moisture, namely water drops, in the air, the moisture, namely the water drops flow into the atomizer 56 through the recovery pipeline 55 and the control valve d57, meanwhile, the atomizer 56 operates to suck the aqueous medium in the water tank 51 and atomize the aqueous medium, and the air in the air inlet pipeline 10 pulls the atomized aqueous medium into the room through the control valve e58, the atomizer 56 and the humidification pipeline 59, so that air in the room is ventilated and humidified;

when the indoor humidity is increased and drying is required, the moisture droplets in the exhaust duct 20 can be recovered by the humidifying member 50, specifically: when the control valve a12 and the control valve c53 are opened and the control valve b21, the control valve d57 and the control valve e58 are closed, the air in the exhaust duct 20 is exhausted to the outside through the filtering duct 52 and the cyclone 54, and in the process, the cyclone 54 strips off moisture, i.e., water droplets in the air, and returns the water droplets to the water tank 51 through the recovery duct 55.

In the embodiments provided in the present disclosure, it should be understood that the disclosed apparatus, device and method may be implemented in other manners. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the modules is only one logical functional division, and there may be other divisions when the actual implementation is performed; the modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the method of the embodiment.

It is also obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference signs in the claims shall not be construed as limiting the claim concerned.

Furthermore, it is obvious that the word "comprising" does not exclude other elements or steps, and the singular does not exclude the plural. A plurality of units or means recited in the system claims may also be implemented by one unit or means in software or hardware. The terms second, etc. are used to denote self-contained vehicular sound collection devices and do not denote any particular order.

Finally, it should be noted that the above embodiments are only used for illustrating the technical method of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical method of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical method of the present invention.

Claims (6)

1. The utility model provides a new fan of self-balancing, includes inlet duct (10) and exhaust duct (20), is provided with heat exchange part (30) between inlet duct (10) and exhaust duct (20), characterized in that, inlet duct (10) are provided with humidity transducer (11) towards outdoor one end, are provided with drying component (40) towards indoor one end, humidity transducer (11) are used for responding to the humidity of outdoor air and transmit the response result for drying component (40) through signal transmission mode, drying component (40) are used for carrying out drying process to outdoor air, be provided with humidification component (50) between inlet duct (10) and exhaust duct (20), humidification component (50) are used for providing atomizing aqueous medium and carry out aqueous medium to the air in the inlet duct (10) simultaneously and retrieve the air in the exhaust duct (20).

2. The self-balancing fresh air machine of claim 1, wherein the drying member (40) comprises a casing (41), one end of the casing (41) is open, the other end is closed, two side surfaces of the casing (41) along the width direction of the casing (41) are respectively provided with a connecting hole (42), one group of connecting holes (42) are communicated with the air inlet pipeline (10), and the other group of connecting holes (42) are communicated with the indoor space;

an inner plate (43) is arranged in the sleeve (41) in a sliding mode, and the inner plate (43) is connected with the sleeve (41) in a sliding mode through a guide piece;

the side surface of the inner plate (43) along the width direction of the shell (41) is provided with a drying hole, two orifices of the drying hole are both provided with a mesh enclosure (46), and a drying agent is arranged in the drying hole;

the side surface of the sleeve (41) is provided with a magnet (48), the side surface of the inner plate (43) is provided with an electromagnet (47), and the electromagnet (47) is electrified and the magnetic adsorption force between the magnets (48) drives the inner plate (43) to move close to the cavity bottom of the sleeve (41).

3. The self-balancing fresh air machine of claim 2, wherein the guide member comprises a guide rod (44) having a guide direction parallel to the extension direction of the casing (41), the guide rod (44) is fixed to the inner plate (43), the guide rod (44) is slidably connected to the casing (41), a spring (45) is sleeved outside the guide rod (44), and the compression elasticity of the spring (45) drives the inner plate (43) to move away from the cavity bottom of the casing (41).

4. A self-balancing fresh air machine according to claim 2 or 3, wherein the air inlet duct (10) is provided with a control valve a (12) between the heat exchanging part (30) and the drying member (40), and the air outlet duct (20) is provided with a control valve b (21) on the outdoor side of the heat exchanging part (30).

5. The self-balancing fresh air machine according to claim 4, wherein the humidifying component (50) comprises a water tank (51) and an atomizer (56), the atomizer (56) is used for sucking the water medium in the water tank (51) and atomizing the water medium;

the humidifying component (50) further comprises a filtering pipeline (52), two ends of the filtering pipeline (52) are communicated with the exhaust pipeline (20), the control valve b (21) is located between two ends of the filtering pipeline (52), a cyclone separator (54) is arranged on the filtering pipeline (52), the cyclone separator (54) is used for receiving air in the exhaust pipeline (20) and carrying out dust centrifugal treatment on the air, and a control valve c (53) located on one side, facing the indoor side, of the cyclone separator (54) is further arranged on the filtering pipeline (52).

6. The self-balancing fresh air machine according to claim 5, wherein the humidifying component (50) further comprises a recovery pipeline (55), one end of the recovery pipeline (55) is communicated with a discharge port of the cyclone separator (54), the other end of the recovery pipeline is connected with an atomizer (56), a connecting nozzle is arranged on the side surface of the water tank (51) and communicated with the recovery pipeline (55), and a control valve d (57) close to the atomizer (56) is arranged on the recovery pipeline (55);

a control valve e (58) used for communicating the atomizer (56) and the air inlet pipeline (10) is arranged between the atomizer (56) and the air inlet pipeline (10), the control valve e (58) is positioned between the heat exchange part (30) and the control valve a (12), a humidifying pipeline (59) is also arranged between the atomizer (56) and the air inlet pipeline (10), one end of the humidifying pipeline (59) is communicated with the atomizer (56), the other end of the humidifying pipeline is communicated with the humidifying pipeline (59), and the end of the humidifying pipeline is positioned between the drying component (40) and the control valve a (12).

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