CN219222614U - Heating device with lighting function - Google Patents

Abstract

The application discloses a heating device with a lighting function, which comprises an air outlet component, a lamp component and a warm air component; the air outlet assembly is positioned between the warm air assembly and the lamp assembly; the air outlet component is provided with an air channel and a heat dissipation channel, the air channel and the heat dissipation channel are isolated from each other, and the heat dissipation channel is used for dissipating heat of a part to be dissipated of the lamp component; the warm air assembly is provided with an air supply part and a first partition piece, wherein the air supply part is communicated with the air duct, and the first partition piece is communicated with the heat dissipation channel and isolates the air supply part from the heat dissipation channel. Therefore, the heating device with the lighting function reduces the temperature of the environment where the lamp assembly is located with lower cost, and prolongs the service life of the lamp assembly.

Description

Heating device with lighting function

Technical Field

The application relates to the technical field of heating equipment, in particular to a heating device with a lighting function.

Background

The bathroom heater with the annular air outlet is characterized in that the lamp assembly is generally arranged at the inner side of the annular air outlet, and the heater is positioned in the air duct, so that hot air flow heated by the heater can blow to the back of the lamp assembly along the air duct, the environment temperature of the lamp assembly is extremely high, and the normal operation of the lamp assembly is not facilitated.

In order to solve the problem, an annular heater adapting to the shape of the annular air outlet is adopted in the related art, and the annular heater is fixed on the side surface of the lamp assembly, so that air flow blown by the fan passes through the back of the lamp assembly, is heated by the heater, and is finally sent into a room through the annular air outlet, and the temperature of the environment where the lamp assembly is positioned is reduced.

However, the ring heater is extremely high in manufacturing cost and low in yield, and since the ring heater is disposed near the ring-shaped air outlet, the configuration of the ring heater can be seen in the appearance of the bathroom heater product, and the influence on the product appearance is large.

Disclosure of Invention

In view of this, the application provides a heating installation with illumination function, can reduce the temperature of lamps and lanterns subassembly place environment with lower cost, improves the life of lamps and lanterns subassembly.

The application adopts the following technical scheme:

the embodiment of the application provides a heating device with a lighting function, which comprises an air outlet component, a lamp component and a warm air component;

the air outlet assembly is positioned between the warm air assembly and the lamp assembly;

the air outlet component is provided with an air duct and a heat dissipation channel, the air duct and the heat dissipation channel are isolated from each other, and the heat dissipation channel is used for dissipating heat of a part to be dissipated of the lamp component;

the warm air assembly is provided with an air supply part and a first partition, the air supply part is communicated with the air duct, and the first partition is communicated with the heat dissipation channel and isolates the air supply part from the heat dissipation channel.

Optionally, the air supply part is closely connected or abutted with the inlet of the air duct; and/or the number of the groups of groups,

the first separating piece is closely connected with or propped against one end of the heat dissipation channel, which is close to the warm air component.

Optionally, the warm air assembly comprises at least one heating module, wherein the heating module is used for heating the air flow flowing through the air supply part;

the at least one heating module has a gap between an orthographic projection on a projection plane and an orthographic projection of the first partition on the projection plane, wherein the projection plane is a plane in which an inlet of the air duct is located.

Optionally, the first partition member is a hollow structural member.

Optionally, the warm air assembly further comprises a bracket, wherein the bracket is provided with a first accommodating cavity and at least one second accommodating cavity;

the first accommodating cavity is used for accommodating the first partition piece, a first side of the first accommodating cavity is opened, and a second side of the first accommodating cavity is provided with a cover plate used for plugging a communication part between the heat dissipation channel and the first partition piece;

the second accommodating cavity is used for accommodating the heating module, and both the first side and the second side of the second accommodating cavity are open;

the first side is far away from the air outlet assembly, and the second side is opposite to the first side.

Optionally, the warm air component further comprises a first connecting structure and a second connecting structure, the first connecting structure and the second connecting structure are connected in a matching way, wherein,

the first connecting structure is arranged on the first partition, and the second connecting structure is arranged on the cavity wall of the first accommodating cavity; and/or the number of the groups of groups,

the first connecting structure is arranged on the side wall of the heating module, and the second connecting structure is arranged on the cavity wall of at least one second accommodating cavity.

Optionally, the first connection structure and the second connection structure are one and the other of a connection sheet and a connection groove respectively;

when the first connecting structure is a connecting piece and the second connecting structure is a connecting groove, the opening end of the connecting groove is positioned at the edge of the bracket, which is close to the second side, and the connecting piece is inserted into the connecting groove.

Optionally, the heating device further comprises an air guide assembly, wherein the air guide assembly comprises a guide piece and a second partition piece, and the guide piece is of a hollow cavity structure;

a first wall of the flow guiding piece is provided with a wind guiding inlet, a second wall of the flow guiding piece is provided with a first wind guiding outlet, wherein the first wall is adjacent to the second wall, and the flow guiding piece is used for changing the flow direction of the air flow flowing in from the wind guiding inlet so that the air flow flows into the air supply part through the first wind guiding outlet;

the second partition is communicated with the first partition and is used for isolating the first air guide outlet and the first partition.

Optionally, a second air guiding outlet is formed in a third wall of the air guiding piece, and the third wall is opposite to the first wall;

the air guide assembly further comprises a baffle member movably connected with the air guide member and capable of being switched between a first position and a second position, wherein,

when in the first position, the baffle member seals the second air guiding outlet so that the air guiding inlet is communicated with the first air guiding outlet;

when in the second position, the baffle member seals the first air guiding outlet so that the air guiding inlet is communicated with the second air guiding outlet.

Optionally, the air guide assembly further comprises a rotating shaft piece and a driving motor;

the baffle piece is connected with the flow guiding piece in a relatively rotatable manner through the rotating shaft piece;

the driving motor is connected with the rotating shaft piece and used for driving the rotating shaft piece to rotate;

when the baffle piece is positioned at the first position, the baffle piece is obliquely arranged in the guide piece, and one end, away from the first air guide outlet, of the baffle piece is closer to the air guide inlet than one end, close to the first air guide outlet.

Optionally, the air duct is provided with two inlets, and the two inlets are respectively positioned at two opposite sides of the heat dissipation channel;

the number of the air supply parts is two, and the two air supply parts are respectively positioned at two opposite sides of the first partition piece;

the number of the first air guide outlets is two, and the two first air guide outlets are respectively positioned at two opposite sides of the second partition;

the positions of the inlet, the air supply part and the first air guide outlet are in one-to-one correspondence.

The heating installation with illumination function that this application embodiment provided, its air-out subassembly is located between warm braw subassembly and the lamps and lanterns subassembly, is provided with the wind channel on the air-out subassembly, and the air supply portion and the wind channel intercommunication of warm braw subassembly to carry the wind channel with the warm braw, again reach the heating effect through the wind channel flow direction external environment. In order to avoid overheat of the environment temperature where the lamp assembly is located caused by warm air flow in the air duct, the air outlet assembly is further provided with a heat dissipation channel for dissipating heat of a part to be dissipated of the lamp assembly, and the heat dissipation channel and the air duct are isolated from each other; the warm air component is also provided with a first separating piece, the first separating piece is used for being communicated with the heat dissipation channel and isolating the air supply part from the heat dissipation channel, so that the warm air flow flowing out of the air supply part is prevented from entering the heat dissipation channel to influence the functions of the lamp component. Compared with the bathroom heater product using the annular heater in the related art, the heating device provided by the embodiment of the application is provided with the heat dissipation channel on the air outlet component and the first partition piece on the warm air component, so that the problem of overhigh environmental temperature of the lamp component is solved with lower manufacturing cost, the normal work of the lamp component is ensured, and the service life of the lamp component is further ensured.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a first exploded view of a heating appliance provided in an embodiment of the present application;

FIG. 2 is a partial exploded view of another heating appliance provided in an embodiment of the present application;

FIG. 3 is an exploded view of another heating appliance provided in an embodiment of the present application at a first view angle;

FIG. 4 is an exploded view of another heating appliance provided in an embodiment of the present application at a second view angle;

FIG. 5 is an exploded view of a warm air assembly provided in an embodiment of the present application;

FIG. 6 is a schematic view illustrating an assembly of a warm air component on a deflector assembly according to a third aspect of the present disclosure, where a baffle member is located at a first position;

FIG. 7 is a schematic view illustrating an assembly of a warm air component on a deflector assembly according to a fourth aspect of the present disclosure, where a baffle member is located at a first position;

FIG. 8 is a schematic view illustrating an assembly of a warm air component on a deflector component according to a fifth aspect of the present disclosure, where a baffle member is located in a second position;

fig. 9 is a second exploded view of a heating appliance provided in an embodiment of the present application.

Reference numerals:

1. an air outlet assembly; 11. an air duct; 111. an inlet; 12. a heat dissipation channel;

2. a lamp assembly; 21. a portion to be heat-dissipated;

3. a warm air component; 31. an air supply unit; 32. a first partition; 33. a heating module; 34. a bracket; 341. a first accommodation chamber; 3411. a cover plate; 342. a second accommodation chamber; 35. a first connection structure; 36. a second connection structure;

4. an air guide assembly; 41. a flow guide; 411. an air inlet; 412. a first air guide outlet; 413. a second air guide outlet; 42. a second separator; 43. a baffle member; 44. a rotating shaft member; 45. and driving the motor.

Detailed Description

In order to make the technical solution and advantages of the present application more apparent, the embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

The embodiment of the application provides a heating device with a lighting function, which adopts a wind heating mode to realize the heating function and is provided with a lamp component for realizing the lighting function. The heating device may be a bathroom warmer, for example.

As shown in fig. 1, the heating device with the lighting function provided by the embodiment of the application comprises an air outlet component 1, a lamp component 2 and a warm air component 3; the air outlet assembly 1 is positioned between the warm air assembly 3 and the lamp assembly 2; the air outlet assembly 1 is provided with an air duct 11 and a heat dissipation channel 12, the air duct 11 and the heat dissipation channel 12 are isolated from each other, and the heat dissipation channel 12 is used for dissipating heat of a part 21 to be dissipated of the lamp assembly 2; the warm air module 3 has an air blowing portion 31 and a first partition 32, the air blowing portion 31 communicates with the air duct 11, and the first partition 32 communicates with the heat radiation passage 12 and isolates the air blowing portion 31 from the heat radiation passage 12.

In the embodiment of the application, the air flow generated by the fan flows from the warm air component 3 to the air outlet component 1 and then flows to the external environment through the air outlet component 1. The heating function of the heating device can be started according to the requirement, wherein under the condition that the heating function is started, the warm air component 3 can heat the air flow flowing through so as to enable the air flow provided by the air outlet component 1 to the external environment to be warm air flow; in the case where the heating function is turned off, the warm air assembly 3 does not heat the air flow flowing therethrough, so that the air flow provided by the air outlet assembly 1 to the outside environment is a cold air flow (i.e., a normal temperature air flow).

The air outlet assembly 1 is provided with an air duct 11 and a heat dissipation channel 12, and the air duct 11 and the heat dissipation channel 12 are isolated from each other and are not communicated with each other; the warm air assembly 3 has an air supply part 31 and a first partition 32, the air supply part 31 is communicated with the air duct 11 so that the warm air assembly 3 can convey air flow into the air duct 11, and the first partition 32 is communicated with the heat dissipation channel 12 and isolates the air supply part 31 from the heat dissipation channel 12 so as to prevent the air flow conveyed by the warm air assembly 3 from entering the heat dissipation channel 12.

To sum up, in the heating device with lighting function provided in the embodiment of the application, the air outlet component 1 is located between the warm air component 3 and the lamp component 2, the air duct 11 is disposed on the air outlet component 1, and the air supply portion 31 of the warm air component 3 is communicated with the air duct 11 to convey the warm air flow to the air duct 11, and then flows to the external environment through the air duct 11 to achieve the heating effect. In order to avoid overheat of the environment temperature where the lamp assembly 2 is located caused by the warm air flow in the air duct 11, the air outlet assembly 1 is further provided with a heat dissipation channel 12 for dissipating heat of a part 21 to be dissipated of the lamp assembly 2, and the heat dissipation channel 12 and the air duct 11 are isolated from each other; the warm air assembly 3 further has a first partition 32, where the first partition 32 is used to communicate with the heat dissipation channel 12 and isolate the air supply portion 31 from the heat dissipation channel 12, so as to avoid that the warm air flowing out of the air supply portion 31 enters into the heat dissipation channel 12 to affect the functions of the lamp assembly 2. Compared with the bathroom heater product using the annular heater in the related art, the heating device provided by the embodiment of the application is provided with the heat dissipation channel 12 on the air outlet component 1 and the first partition piece 32 on the warm air component 3, so that the problem of overhigh environmental temperature of the lamp component 2 is solved with lower manufacturing cost, the normal operation of the lamp component 2 is ensured, and the service life of the lamp component 2 is further ensured.

In some embodiments of the present application, as shown in fig. 2, the first partition 32 is closely connected to or abuts against an end of the heat dissipation channel 12 near the warm air component 3; and/or the air supply part 31 is closely connected or abutted with the inlet 111 of the air duct 11.

When the first partition 32 is closely connected to or abuts against one end of the heat dissipation channel 12 near the warm air component 3, there is no gap between the first partition 32 and the heat dissipation channel 12, which allows the air flow to flow through, and even if the air flow escapes from the air supply portion 31, the escaping air flow cannot enter the heat dissipation channel 12 at the connection position of the first partition 32 and the heat dissipation channel 12. When the air blowing portion 31 is closely connected to or abuts against the inlet 111 of the duct 11, there is no gap between the air blowing portion 31 and the inlet 111 of the duct 11, and thus the air flows into the duct 11 through the air blowing portion 31 and the inlet 111 of the duct 11, and does not enter the heat dissipation duct 12.

Optionally, a sealing member is provided at the junction of the first partition 32 and the heat dissipation path 12, and at the junction of the air blowing portion 31 and the inlet 111 of the air duct 11, for achieving a closed connection. The seal may be a rubber seal, for example.

In some embodiments of the present application, as shown in fig. 2, the warm air assembly 3 includes at least one heating module 33, and the heating module 33 is configured to heat the air flow flowing through the air supply portion 31; the front projection of the at least one heating module 33 on the projection plane, which is the plane in which the inlet 111 of the air duct 11 is located, and the front projection of the first partition 32 on the projection plane have a gap therebetween.

The front projection of the first partition 32 on the projection plane and the front projection of each heating module 33 on the projection plane have a gap, so that the heater has low air heating efficiency on the first partition 32, and the influence on the heat dissipation effect of the heat dissipation channel 12 caused by the overhigh temperature of the environment where the first partition 32 is located is avoided.

Alternatively, the heating module 33 is a grill heater, and the air flow may flow through gaps between inner grills of the grill heater. The grill heater may be disposed inside the air blowing part 31 so that the air flow flows through the grill heater while also flowing through the air blowing part 31, thereby improving the heating efficiency of the air flow.

In some embodiments, the first partition 32 is a hollow structure, so that air at the first partition 32 flows, thereby improving the heat dissipation efficiency of the first partition 32 and reducing the influence of the arrangement environment of the heater on the heat dissipation effect of the heat dissipation channel 12.

As shown in fig. 3 and 4, in some embodiments of the present application, the warm air assembly 3 further includes a bracket 34, the bracket 34 having a first receiving cavity 341 and at least one second receiving cavity 342; the first accommodating cavity 341 is used for accommodating the first partition 32, a first side of the first accommodating cavity 341 is open, and a second side of the first accommodating cavity 341 is provided with a cover plate 3411 for blocking a communication part between the heat dissipation channel 12 and the first partition 32; the second accommodating cavity 342 is used for accommodating the heating module 33, and both the first side and the second side of the second accommodating cavity 342 are open; the first side is a side far away from the air outlet component 1, and the second side is opposite to the first side.

The bracket 34 is used for mounting the first partition 32 and the at least one heating module 33. The first accommodating cavity 341 corresponds to the heat dissipation channel 12 in position, the first partition 32 is installed in the first accommodating cavity 341, a first side of the first accommodating cavity 341 is opened, and a second side of the first accommodating cavity 341 is closed by the cover plate 3411, so that hot air flow in the first partition 32 is prevented from entering the heat dissipation channel 12 through the first accommodating cavity 341. Optionally, a cover plate 3411 on the second side of the first accommodating cavity 341 is closely connected to or abuts against the heat dissipation channel 12.

The second accommodating cavity 342 corresponds to the position of the inlet 111 of the air duct 11, and the at least one heating module 33 is correspondingly installed in the at least one second accommodating cavity 342, and the first side and the second side of the second accommodating cavity 342 are both opened, so that air flow can flow through the heating module 33 in the second accommodating cavity 342 and enter the inlet 111 of the air duct 11. The at least one second accommodating chamber 342 is used to form the air supply portion 31 of the warm air assembly 3. Optionally, the end of the second accommodation chamber 342 on the second side is closely connected or abutted with the inlet 111 of the air duct 11.

With continued reference to fig. 4, in some embodiments of the present application, the warm air assembly 3 further includes a first connection structure 35 and a second connection structure 36, the first connection structure 35 and the second connection structure 36 being cooperatively connected; wherein the first connection structure 35 is disposed on the first partition 32, and the second connection structure 36 is disposed on a wall of the first receiving chamber 341; and/or the first connection structure 35 is provided on a side wall of the heating module 33 and the second connection structure 36 is provided on a cavity wall of the at least one second receiving cavity 342.

The fixation of the first partition 32 and/or the heating module 33 on the bracket 34 can be achieved by the cooperation between the first connection structure 35 and the second connection structure 36. In some embodiments, as shown in fig. 4 and 5, the first and second connection structures 35 and 36 are one and the other of a connection tab and a connection slot, respectively; when the first connecting structure 35 is a connecting piece and the second connecting structure 36 is a connecting groove, the opening end of the connecting groove is located at the edge of the bracket 34 near the second side, and the connecting piece is inserted into the connecting groove.

Referring to fig. 5, connecting pieces are connected to the side walls of the heating module 33 and the inner walls of the first partition 32, and connecting grooves are formed at corresponding positions on the chamber walls of the first and second receiving chambers 341 and 342 of the bracket 34, and since the heating module 33 and the first partition 32 are installed from the second side of the bracket 34, the open ends of the connecting grooves are located at edges of the bracket 34 near the second side so that the connecting pieces are inserted into the connecting grooves through the open ends.

In some embodiments, after the connection piece is inserted into the connection groove, the heating module 33 and the cavity wall of the second accommodating cavity 342 are further connected secondarily by a screw or a buckle, so as to improve the connection firmness and reliability.

Alternatively, as shown in fig. 4 and 5, the housing of the heating module 33, the first partition 32, and the first connection structure 35 are integrally formed, thereby constituting an integrated grill heater.

In some embodiments of the present application, as shown in fig. 6, the heating device provided in the embodiment of the present application further includes an air guiding assembly 4, where the air guiding assembly 4 includes a guiding element 41 and a second partition 42, and the guiding element 41 is a hollow cavity structure. The first wall of the guiding element 41 is provided with an air guiding inlet 411, and the second wall of the guiding element 41 is provided with an air guiding outlet, wherein the first wall is adjacent to the second wall, and the guiding element 41 is used for changing the flow direction of the air flowing in from the air guiding inlet 411, so that the air flows through the first air guiding outlet 412 and flows into the air supplying part 31. The second partition 42 is connected to the air guide 41 and communicates with the first partition 32, and the second partition 42 serves to isolate the first air guide outlet 412 from the first partition 32.

As shown in fig. 6, the first air guiding outlet 412 is communicated with the air supplying part 31, and the high-speed air flow generated by the fan assembly enters the air guiding inlet 411 along the first direction and flows out to the air supplying part 31 along the second direction through the first air guiding outlet 412 under the constraint of the air guiding member 41. Wherein the first direction is parallel to the opening direction of the air inlet 411, for example, may be a horizontal direction; the second direction is parallel to the opening direction of the first air guiding outlet 412, and may be, for example, a vertical direction. Alternatively, the first air guiding outlet 412 is closely connected to or abutted against the air blowing portion 31, that is, the first air guiding outlet 412 is closely connected to or abutted against the second side of the corresponding second accommodating chamber 342.

The second partition 42 is in communication with the first partition 32 and is used for isolating the first air guiding outlet 412 from the first partition 32, so as to prevent the high-temperature air near the heating module 33 from entering the first partition 32 under the driving of the air flow, and thus the heat dissipation effect of the heat dissipation channel 12 and the first partition 32 is not affected. In some embodiments, as shown in fig. 6, the second partition 42 may be connected in the cavity of the flow guide 41 to partition the inner space of the flow guide 41 into two parts, each having the air guide inlet 411 and the first air guide outlet 412. Optionally, the second divider 42 is sealingly connected to or against the first divider 32.

In some embodiments, as shown in fig. 7 and 8, a second air guiding outlet 413 is formed on the third wall of the air guiding element 41; the air guiding assembly 4 further comprises a baffle member 43; the baffle member 43 is movably connected with the air guiding member 41 and can be switched between a first position and a second position, wherein when the baffle member 43 is positioned at the first position, the second air guiding outlet 413 is blocked by the baffle member 43 so that the air guiding inlet 411 is communicated with the first air guiding outlet 412; when in the second position, the baffle member 43 blocks the first air guiding outlet 412 such that the air guiding inlet 411 communicates with the second air guiding outlet 413.

By changing the position of the baffle member 43, switching between the heating function and the ventilation function of the heating apparatus can be achieved. Fig. 6 and 7 show the structure of the deflector element 43 in the first position. At this time, the air flow entering from the diversion inlet 111 changes its direction and flows out from the first air guiding outlet 412 and flows into the heating module 33, and when the heating function is turned on, the heating module 33 works to heat the air flow flowing through, so that the air outlet assembly 1 delivers the warm air flow to the external environment.

Fig. 8 shows the structure of the deflector assembly when the shutter member 43 is in the second position. At this time, the air flow entering from the diversion inlet 111 directly flows out from the second air guiding outlet 413, so as to realize the ventilation function. Since the third wall is opposite to the first wall, the second air guiding outlet 413 is opposite to the air guiding inlet 411, and the air flow does not need to flow out in a reversing way, so that the ventilation efficiency is high.

In some embodiments of the present application, the position switching of the baffle member 43 may be achieved by means of rotation. As shown in fig. 8, the wind guiding assembly 4 further includes a rotating shaft member 44 and a driving motor 45, and the baffle member 43 is rotatably connected with the guiding member 41 through the rotating shaft member 44; the driving motor 45 is connected with the rotating shaft member 44 and is used for driving the rotating shaft member 44 to rotate so as to drive the baffle member 43 to switch between the first position and the second position; wherein, when in the first position, the baffle member 43 is disposed obliquely inside the air guiding member 41, and an end of the baffle member 43 away from the first air guiding outlet 412 is closer to the air guiding inlet 411 than an end close to the first air guiding outlet 412.

Illustratively, as shown in fig. 8, a mounting hole is formed in the flow guiding member 41, a rotating shaft member 44 is disposed through the mounting hole and is rotatable relative to the flow guiding member 41, and one end of the rotating shaft member 44 protrudes from one side of the flow guiding member 41; the driving motor 45 is installed on the side wall of the flow guiding member 41 and is connected with the rotating shaft member 44 extending out of the flow guiding member 41 to drive the rotating shaft member 44 to rotate; the baffle member 43 is fixedly disposed in the cavity of the flow guiding member 41 and fixedly connected to the rotating shaft member 44.

When the baffle member 43 is located at the first position, the baffle member 43 can block the second air guiding outlet 413, and the baffle member 43 is disposed inside the air guiding member 41 obliquely with respect to the opening direction of the second air guiding outlet 413, at this time, an end of the air guiding member 41 away from the first air guiding outlet 412 is closer to the air guiding inlet 411 than an end of the air guiding member 41 close to the first air guiding outlet 412, so as to guide the airflow to flow in the direction of the first air guiding outlet 412. When the baffle member 43 is located at the second position, the baffle member 43 can seal the first air guiding outlet 412, and at this time, the edge of the baffle member 43 contacts the inner wall of the air guiding member 41.

In the embodiment of the present application, the inclined arrangement refers to an arrangement that is neither parallel nor perpendicular.

In some embodiments of the present application, as shown in fig. 9, the air duct 11 has two inlets 111, and the two inlets 111 are respectively located on opposite sides of the heat dissipation channel 12; the number of the air supply parts 31 is two, and the two air supply parts 31 are respectively positioned at two opposite sides of the first partition 32; the number of the first air guiding outlets 412 is two, the two first air guiding outlets 412 are respectively positioned at two opposite sides of the second partition member 42, and the positions of the inlet 111, the air supplying part 31 and the first air guiding inlet 411 are in one-to-one correspondence.

Therefore, in the heating device with lighting function provided in the embodiment of the present application, in order to avoid adverse effects of warm air flow in the air duct 11 of the air outlet assembly 1 on the use environment of the lamp assembly 2, the air outlet assembly 1 is provided with a heat dissipation channel 12 for the portion 21 to be heat-dissipated of the lamp assembly 2, and the heat dissipation channel 12 and the air duct 11 are isolated from each other; and, on the flow path of the air flow, the heat dissipation channel 12 is further isolated from the air supply part 31 and the flow guiding part 41 for transmitting the air flow by the first partition member 32 and the second partition member 42, so that the warm air flow is prevented from entering the heat dissipation channel 12 to affect the normal operation and the service life of the lamp assembly 2. Moreover, compared with the bathroom warmer product using the ring heater in the related art, the heating device provided by the embodiment of the application has the advantages that the heat dissipation channel 12 is arranged on the air outlet component 1, the first partition piece 32 is arranged on the warm air component 3, and the second partition piece 42 is arranged on the flow guide piece 41, so that the problem that the environment temperature of the lamp component 2 is too high is solved at lower cost, and better economy is realized.

In this application, it should be understood that the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated.

The foregoing is merely for facilitating understanding of the technical solutions of the present application by those skilled in the art, and is not intended to limit the present application. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (11)

1. The heating device with the lighting function is characterized by comprising an air outlet component (1), a lamp component (2) and a warm air component (3);

the air outlet assembly (1) is positioned between the warm air assembly (3) and the lamp assembly (2);

the air outlet assembly (1) is provided with an air duct (11) and a heat dissipation channel (12), the air duct (11) and the heat dissipation channel (12) are isolated from each other, and the heat dissipation channel (12) is used for dissipating heat of a part (21) to be cooled of the lamp assembly (2);

the warm air assembly (3) is provided with an air supply part (31) and a first partition (32), the air supply part (31) is communicated with the air duct (11), and the first partition (32) is communicated with the heat dissipation channel (12) and isolates the air supply part (31) from the heat dissipation channel (12).

2. Heating installation according to claim 1, wherein the air supply (31) is connected in a closed manner to or against the inlet (111) of the air duct (11); and/or the number of the groups of groups,

the first separating piece (32) is closely connected with or props against one end of the heat dissipation channel (12) close to the warm air component (3).

3. Heating installation according to claim 1 or 2, characterized in that the warm air assembly (3) comprises at least one heating module (33), the heating module (33) being adapted to heat the air flow through the air supply (31);

a clearance is formed between the front projection of the at least one heating module (33) on a projection plane and the front projection of the first partition (32) on the projection plane, wherein the projection plane is the plane in which the inlet (111) of the air duct (11) is located.

4. A heating installation according to claim 3, wherein the first partition (32) is a hollowed-out structural member.

5. A heating installation according to claim 3, wherein the warm air assembly (3) further comprises a bracket (34), the bracket (34) having a first accommodation cavity (341) and at least one second accommodation cavity (342);

the first accommodating cavity (341) is used for accommodating the first partition (32), a first side of the first accommodating cavity (341) is opened, and a second side of the first accommodating cavity is provided with a cover plate (3411) used for blocking a communication part between the heat dissipation channel (12) and the first partition (32);

the second accommodating cavity (342) is used for accommodating the heating module (33), and a first side and a second side of the second accommodating cavity (342) are both open;

the first side is a side far away from the air outlet assembly (1), and the second side is opposite to the first side.

6. Heating installation according to claim 5, characterized in that the warm air module (3) further comprises a first connection structure (35) and a second connection structure (36), the first connection structure (35) and the second connection structure (36) being connected in a mating manner, wherein,

the first connection structure (35) is arranged on the first partition (32), and the second connection structure (36) is arranged on the cavity wall of the first accommodating cavity (341); and/or the number of the groups of groups,

the first connection structure (35) is arranged on the side wall of the heating module (33), and the second connection structure (36) is arranged on the cavity wall of at least one second accommodating cavity (342).

7. Heating installation according to claim 6, wherein the first connection structure (35) and the second connection structure (36) are one and the other of a connecting piece and a connecting groove, respectively;

wherein when the first connecting structure (35) is a connecting piece and the second connecting structure (36) is a connecting groove, the opening end of the connecting groove is positioned at the edge of the bracket (34) close to the second side, and the connecting piece is inserted into the connecting groove.

8. A heating installation according to claim 3, characterized in that the heating installation further comprises an air guiding assembly (4), the air guiding assembly (4) comprising a flow guiding member (41) and a second partition member (42), the flow guiding member (41) being of an internally hollow cavity structure;

a first wall of the flow guiding piece (41) is provided with an air guiding inlet (411), a second wall of the flow guiding piece (41) is provided with a first air guiding outlet (412), wherein the first wall is adjacent to the second wall, and the flow guiding piece (41) is used for changing the flow direction of air flow flowing in from the air guiding inlet (411) so that the air flow flows into the air supply part (31) through the first air guiding outlet (412);

the second partition (42) communicates with the first partition (32) for isolating the first air guiding outlet (412) from the first partition (32).

9. Heating installation according to claim 8, wherein a second air guiding outlet (413) is provided in a third wall of the air guiding element (41), said third wall being opposite to the first wall;

the air guide assembly (4) further comprises a baffle member (43), the baffle member (43) is movably connected with the air guide member (41) and can be switched between a first position and a second position, wherein,

when in the first position, the baffle member (43) blocks the second air guiding outlet (413) so that the air guiding inlet (411) communicates with the first air guiding outlet (412);

when in the second position, the baffle member (43) blocks the first air guiding outlet (412) so that the air guiding inlet (411) communicates with the second air guiding outlet (413).

10. Heating installation according to claim 9, wherein the air guiding assembly (4) further comprises a shaft member (44) and a drive motor (45);

the baffle piece (43) is connected with the flow guiding piece (41) in a relatively rotatable manner through the rotating shaft piece (44);

the driving motor (45) is connected with the rotating shaft piece (44) and is used for driving the rotating shaft piece (44) to rotate;

wherein, when in the first position, the baffle member (43) is obliquely arranged inside the flow guiding member (41), and one end of the baffle member (43) away from the first air guiding outlet (412) is closer to the air guiding inlet (411) than one end close to the first air guiding outlet (412).

11. Heating installation according to claim 8, wherein the air duct (11) has two said inlets (111), the two said inlets (111) being located on opposite sides of the heat dissipation channel (12), respectively;

the number of the air supply parts (31) is two, and the two air supply parts (31) are respectively positioned at two opposite sides of the first separating piece (32);

the number of the first air guide outlets (412) is two, and the two first air guide outlets (412) are respectively positioned at two opposite sides of the second partition piece (42);

the positions of the inlet (111), the air supply part (31) and the first air guide outlet (412) are in one-to-one correspondence.

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