CN219283510U - Buried air conditioning system - Google Patents

Abstract

The utility model relates to the technical field of air conditioning equipment, in particular to a buried air conditioning system; comprises a ground temperature regulating system, an air communication device and an air conveying device; when the scheme is used, the ground temperature regulating system between the floor and the floor is started, and the air circulation space between the floor and the floor can be quickly regulated when the ground temperature regulating system is started; and then starting the air conveying device, conveying the air after temperature adjustment in the air circulation space into the indoor space through the air conveying device, forming negative pressure in the air conveying device when the air conveying device extracts the air in the air circulation space, and conveying and temperature adjusting the air in the indoor space into the air circulation space through the air communication device communicated with the indoor space and the air circulation space, so that the air in the air circulation space and the indoor air are continuously circulated, the rising or falling of the air in the indoor space is accelerated, the indoor space is quickly warmed, and the experience of a user is improved.

Description

Buried air conditioning system

Technical Field

The utility model relates to the technical field of air conditioning equipment, in particular to a buried air conditioning system.

Background

The ground temperature regulating system is a common ground heating system in the prior art, is arranged between the indoor floor and the floor, and uniformly heats or cools the indoor floor by using a heating medium or a cooling medium between the whole floor and the floor so as to achieve the heating or cooling effect; in order to achieve the effect of more uniform temperature adjustment, a gap is arranged between the floor surface and the floor in the prior art to form an air circulation space; the floor heating system with the heat buffer layer disclosed in the patent number CN201620648814.0 comprises a gap arranged between the filling layer 20 and the floor heating floor 10, the gap forms a heat buffer layer 60, the heat buffer layer 60 plays a role in heat mixing, the heat transfer speed in the air is higher, and the temperature of the whole heat buffer layer 60 is convenient to be regulated; the large-area heat buffer layer 60 enables the temperature of the floor heating board 10 to be mainly transferred through the air of the heat buffer layer 60, so that the temperature of the floor heating board 10 is uniform, and the heat buffer layer 60 is the air circulation space. This kind of setting can let the temperature on floor more even, but when the ground temperature control system of floor below was operated, the process of its temperature that produces in the interior space above the transmission floor required longer time, leads to the interior space to rise and the speed of cooling is too slow, influences user's experience.

Based on this, the applicant considered to design a buried air conditioning system capable of rapidly adjusting the temperature of an indoor space.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to solve the technical problems that: how to provide a buried air conditioning system capable of rapidly adjusting the temperature of an indoor space.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the underground air conditioning system comprises a ground temperature regulating system arranged between an indoor floor and a floor, wherein a hollow air circulation space is arranged between the floor and the floor; the device also comprises an air communication device and an air conveying device;

the air conveying device is used for extracting air in the air circulation space and conveying the air to the indoor space.

The technical scheme has the following working principle and advantages that:

when the scheme is used, the ground temperature regulating system between the floor and the floor is started, and the air circulation space between the floor and the floor can be quickly regulated when the ground temperature regulating system is started; and then starting the air conveying device, conveying the air after temperature adjustment in the air circulation space into the indoor space through the air conveying device, forming negative pressure in the air conveying device when the air conveying device extracts the air in the air circulation space, and conveying and temperature adjusting the air in the indoor space into the air circulation space through the air communication device communicated with the indoor space and the air circulation space, so that the air in the air circulation space and the indoor air are continuously circulated, the rising or falling of the air in the indoor space is accelerated, the indoor space is quickly warmed, and the experience of a user is improved.

Further, the air communication device is connected with the first air port communicated with the air circulation space, the second air port communicated with the indoor space and the first air pipe communicated with the first air port and the second air port.

Further, the air conveying device comprises a third air port communicated with the air circulation space, a second air pipe and an air circulation assembly; the air circulation assembly comprises an air inlet cavity, a disinfection cavity and an air outlet cavity, the second air pipe is communicated with the air inlet cavity and the third air port, the air inlet cavity is used for extracting air in the air circulation space and conveying the air to the disinfection cavity, and the air outlet cavity is used for extracting air in the disinfection cavity and conveying the air to the indoor space.

Further, the air conveying device further comprises a shell, one end of the second air pipe is fixedly connected with the bottom of the shell, the other end of the second air pipe is fixedly connected with the third air port, and the air inlet cavity, the disinfection cavity and the air outlet cavity are all arranged in the shell.

Further, the two sides of the disinfection cavity in the shell are respectively provided with the air inlet cavity and the air outlet cavity; the air inlet cavity is provided with a first communication port communicated with the air pipe II and a second communication port communicated with the disinfection cavity, and a first fan is arranged in the air inlet cavity; a sterilizing lamp is arranged in the sterilizing cavity; the air outlet cavity is provided with a communication port III communicated with the disinfection cavity and an air outlet communicated with the indoor space, and a fan II is arranged in the air outlet cavity.

Further, a control module and a first temperature sensor are further installed in the air inlet cavity, a negative ion generator is further installed in the air outlet cavity, and the control module is in communication connection with the first temperature sensor, the negative ion generator, the first fan and the second fan.

Further, the air conveying device further comprises a fresh air component communicated with the air outlet cavity.

Further, the new trend subassembly includes the new trend chamber, the air intake with outside air intercommunication has been seted up in the new trend chamber, new trend chamber internally mounted has fan IV and filter screen, the new trend chamber with disinfection chamber intercommunication.

Further, the new trend subassembly still includes the chamber of airing exhaust, the chamber of airing exhaust has seted up the air exit one with indoor air intercommunication and has been communicated with outside air's air exit two, the intracavity portion of airing exhaust has fan three.

Further, the air communication device and the air conveying device are fixedly installed in the wall surface.

Drawings

FIG. 1 is a schematic diagram of an embodiment of an embedded air conditioning system;

FIG. 2 is a schematic view of an air communication device according to an embodiment of the present utility model when the air communication device is installed on a wall surface;

FIG. 3 is a schematic view of an air delivery device according to an embodiment of the present utility model when installed on a wall surface;

FIG. 4 is a schematic cross-sectional elevation view of an air delivery device according to an embodiment of the present utility model;

FIG. 5 is a schematic top view of an air delivery device according to an embodiment of the present utility model;

FIG. 6 is a schematic top view of a cross-sectional structure of an air delivery device according to an embodiment of the present utility model;

in the above figures: 10. floor surface; 11. a ground temperature regulating system; 12. a floor; 13. a wall surface; 14. an air circulation space; 100. an air communication device; 110. a first tuyere; 120. an air pipe I; 130. a second tuyere; 140. a second temperature sensor; 200. an air delivery device; 210. an air port III; 220. an air pipe II; 230. a housing; 231. a control panel; 300. an air circulation assembly; 310. an air inlet cavity; 311. a first communication port; 312. a first temperature sensor; 313. a control module; 314. a first fan; 315. a second communication port; 320. a disinfection chamber; 321. a sterilizing lamp; 330. an air outlet cavity; 331. a third communication port; 332. a second fan; 333. a negative ion generator; 334. an air outlet; 400. fresh air component; 410. an exhaust cavity; 411. a third fan; 412. an exhaust outlet I; 413. an exhaust outlet II; 420. a fresh air cavity; 421. a fan IV; 422. a filter screen; 423. and an air inlet.

Detailed Description

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Referring to fig. 1 to 6 together, the present embodiment provides a buried air conditioning system comprising a floor temperature control system 11 installed between an indoor floor 10 and a floor 12, a hollow air circulation space 14 being provided between the floor 10 and the floor 12; characterized by further comprising an air communication device 100 and an air conveying device 200;

the air communication device 100 communicates the indoor space with the air circulation space 14, and the air delivery device 200 is used for extracting air in the air circulation space 14 and delivering the air to the indoor space.

When the scheme is used, the ground temperature regulating system 11 between the floor 10 and the floor 12 is started, and the ground temperature regulating system 11 can quickly regulate the temperature of the air circulation space 14 between the floor 10 and the floor 12 when being started; and then, the air conveying device 200 is started, the air in the air circulation space 14 is conveyed into the indoor space through the air conveying device 200, when the air conveying device 200 extracts the air in the air circulation space 14, negative pressure is formed in the air conveying device, the air communicating device 100 communicating the indoor space with the air circulation space 14 can convey the air in the indoor space into the air circulation space 14 and regulate the temperature, so that the air in the air circulation space 14 and the indoor air are continuously circulated, the rising or falling of the air in the indoor space is accelerated, the indoor space is quickly regulated, and the experience of a user is improved.

Preferably, as shown in fig. 1 and 2, the air communication device 100 includes a first tuyere 110 communicating with the air circulation space 14, a second tuyere 130 communicating with the indoor space, and a first air duct 120 communicating the first tuyere 110 with the second tuyere 130; the top end of the first air pipe 120 is fixedly connected with the second air port 130, the bottom end of the first air pipe is fixedly connected with the first air port 110, and indoor air flows to the air circulation space 14 through the second air port 130, the first air pipe 120 and the first air port 110 in sequence.

Preferably, as shown in fig. 1, 3, 4 and 6, the air delivery device 200 includes a third tuyere 210, a second air duct 220 and an air circulation assembly 300, which are communicated with the air circulation space 14; the air circulation assembly 300 comprises an air inlet cavity 310, a disinfection cavity 320 and an air outlet cavity 330, the air pipe II 220 is communicated with the air inlet cavity 310 and the air port III 210, the air in the air circulation space 14 is extracted by the air inlet cavity 310, conveyed to the disinfection cavity 320 through the air pipe II 220, disinfected by the disinfection cavity 320, and the disinfected air in the disinfection cavity 320 is extracted by the air outlet cavity 330 and conveyed to the indoor space.

Specifically, the air delivery device 200 further includes a housing 230, one end of the second air pipe 220 is fixedly connected to the bottom of the housing 230, the other end is fixedly connected to the third air port 210, and the air inlet cavity 310, the disinfection cavity 320 and the air outlet cavity 330 are all disposed in the housing 230; the two sides of the disinfection cavity 320 in the shell 230 are respectively provided with an air inlet cavity 310 and an air outlet cavity 330; the air inlet cavity 310 is provided with a first communication port 311 communicated with the second air pipe 220 and a second communication port 315 communicated with the disinfection cavity 320, and a first fan 314 is arranged in the air inlet cavity 310; a sterilizing lamp 321 is installed in the sterilizing chamber 320; the air outlet cavity 330 is provided with a third communication port 331 communicated with the disinfection cavity 320 and an air outlet 334 communicated with the indoor space, and a second fan 332 is arranged in the air outlet cavity 330; because the first communication port 311 is communicated with the second air pipe 220 and the air inlet cavity 310, when the first fan 314 in the air inlet cavity 310 is started, air entering the second air pipe 220 through the third air port 210 can be extracted into the air inlet cavity 310, and the air can be conveyed into the disinfection cavity 320 through the second communication port 315; the sterilizing lamp 321 in the sterilizing chamber 320 sterilizes the air introduced therein; because the third communication port 331 is connected with the disinfection cavity 320 and the air outlet cavity 330, when the second fan 332 in the air outlet cavity 330 is started, the disinfected air in the disinfection cavity 320 can be extracted into the air inlet cavity 310 and is conveyed into the indoor space through the air outlet 334; the air delivery device 200 can continuously discharge the air, which has been subjected to temperature adjustment, in the air circulation space 14 to the indoor air.

More specifically, the sterilizing lamp 321 may directly employ an ultraviolet lamp in the related art.

Preferably, as shown in fig. 1, 4 and 5, the air delivery device 200 further includes a fresh air component 400 communicated with the air outlet cavity 330, and the fresh air component 400 can regulate indoor air quality.

Specifically, the fresh air assembly 400 includes a fresh air cavity 420, an air inlet 423 communicated with external air is formed in the fresh air cavity 420, a fan four 421 and a filter screen 422 are installed in the fresh air cavity 420, the fresh air cavity 420 is communicated with the disinfection cavity 320, when the fan four 421 is started, outdoor air can be extracted into the fresh air cavity 420, the filter screen 422 in the fresh air cavity 420 can filter the outdoor air, the filtered air is conveyed to the disinfection cavity 320, and after the disinfection of the air entering the disinfection cavity is completed, the air enters the room through the air outlet cavity 330; the fresh air assembly 400 further comprises an air exhaust cavity 410, wherein the air exhaust cavity 410 is provided with an air outlet I412 communicated with indoor air and an air outlet II 413 communicated with external air, and a fan III 411 is arranged in the air exhaust cavity 410; when the third fan 411 in the exhaust cavity 410 is started, the first air outlet 412 can be drawn into the exhaust cavity 410, and the air in the first air outlet can be quickly discharged outdoors through the second air outlet 413; the exhaust chamber 410 can rapidly exhaust air with poor indoor quality, and the fresh air chamber 420 can rapidly exhaust the outdoor air into the room after processing.

Specifically, as shown in fig. 1, 4, 5 and 6, the fresh air component 400 and the air circulation component 300 are both installed in the casing 230, so that the integrity is higher; the interior of the shell 230 is divided into a lower half part with an air inlet cavity 310, a disinfection cavity 320 and an air outlet cavity 330, and an upper half part is a fresh air cavity 420, wherein the fresh air cavity 420 comprises a filter screen 422 which is transversely arranged, and the air exhaust cavity 410 is positioned above the filter screen 422.

Preferably, as shown in fig. 4 and 6, a control module 313 and a first temperature sensor 312 are further installed in the air inlet cavity 310, and a negative ion generator 333 is further installed in the air outlet cavity 330, wherein the control module 313 is in communication connection with the first temperature sensor 312, the negative ion generator 333, a first fan 314 and a second fan 332; specifically, the second tuyere 130 is provided with the second temperature sensor 140, the third fan 411, the fourth fan 421 and the sterilizing lamp 321 are all in communication connection with the control module 313, and the control module 313 can collect information of the first temperature sensor 312 and the second temperature sensor 140 and can also turn on or turn off the first fan 314, the second fan 332, the third fan 411, the fourth fan 421, the sterilizing lamp 321 and the negative ion generator 333; more specifically, the second tuyere 130 is disposed below the indoor space, and the air inlet chamber 310 is disposed above the indoor space, so that the first temperature sensor 312 can detect the temperature above the indoor space, and the second temperature sensor 140 can detect the temperature below the indoor space;

specifically, as shown in fig. 1, a control panel 231 is disposed outside the casing, and the control panel 231 can limit information collected by the control module 313 and can operate the control module 313, and the first fan 314, the second fan 332, the third fan 411, the fourth fan 421, the sterilizing lamp 321 and the negative ion generator 333 are turned on or off by the control panel 231.

Specifically, as shown in fig. 1, detachable filtering shutters are disposed at the first air inlet 110, the second air inlet 130, the third air inlet 210, the air outlet 334, the first air outlet 412, the second air outlet 413, and the air inlet 423.

Preferably, as shown in fig. 2 and 3, the air communication device 100 and the air delivery device 200 are fixedly installed in the wall surface 13, and the air communication device 100 and the air delivery device 200 are directly installed in the wall surface 13 of the building without occupying indoor space, and of course, the air communication device 100 and the air delivery device 200 may be fixedly installed on the wall surface 13 or installed at a spaced wall surface 13.

Specifically, the air circulation assembly 300, the fresh air chamber 420 and the exhaust chamber 410 can be operated independently or together to perform various adjustments on the indoor air to meet the needs of the user.

Specifically, the second air duct 220 may adopt a silencing box in the prior art, so as to reduce noise during operation of the device.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims (10)

1. The underground air conditioning system comprises a ground temperature regulating system arranged between an indoor floor and a floor, wherein a hollow air circulation space is arranged between the floor and the floor; the device is characterized by also comprising an air communication device and an air conveying device;

the air conveying device is used for extracting air in the air circulation space and conveying the air to the indoor space.

2. The underground air conditioning system as recited in claim 1, wherein the air communication means is a first air port communicating with the air circulation space, a second air port communicating with the indoor space, and a first air duct communicating the first air port and the second air port.

3. The buried air conditioning system as set forth in claim 1 wherein said air delivery means includes a third tuyere, a second air duct and an air circulation assembly in communication with said air circulation space; the air circulation assembly comprises an air inlet cavity, a disinfection cavity and an air outlet cavity, the second air pipe is communicated with the air inlet cavity and the third air port, the air inlet cavity is used for extracting air in the air circulation space and conveying the air to the disinfection cavity, and the air outlet cavity is used for extracting air in the disinfection cavity and conveying the air to the indoor space.

4. The underground air conditioning system as recited in claim 3 wherein the air delivery device further comprises a housing, wherein the second air pipe has one end fixedly connected to the bottom of the housing and the other end fixedly connected to the third air port, and the air inlet chamber, the disinfection chamber and the air outlet chamber are all disposed in the housing.

5. The buried air conditioning system of claim 4 wherein said disinfection chamber within said housing is flanked by said air inlet chamber and said air outlet chamber, respectively; the air inlet cavity is provided with a first communication port communicated with the air pipe II and a second communication port communicated with the disinfection cavity, and a first fan is arranged in the air inlet cavity; a sterilizing lamp is arranged in the sterilizing cavity; the air outlet cavity is provided with a communication port III communicated with the disinfection cavity and an air outlet communicated with the indoor space, and a fan II is arranged in the air outlet cavity.

6. The underground air conditioning system of claim 5, wherein a control module and a first temperature sensor are further installed in the air inlet cavity, and a negative ion generator is further installed in the air outlet cavity, and the control module is in communication connection with the first temperature sensor, the negative ion generator, the first fan and the second fan.

7. The buried air conditioning system as set forth in claim 3 wherein said air delivery apparatus further comprises a fresh air component in communication with said air outlet chamber.

8. The buried air conditioning system as set forth in claim 7 wherein said fresh air module includes a fresh air chamber, said fresh air chamber having an air inlet opening communicating with the outside air, said fresh air chamber having a fan four and a filter screen mounted therein, said fresh air chamber communicating with said disinfection chamber.

9. The underground air conditioning system of claim 8, wherein the fresh air component further comprises an exhaust cavity, the exhaust cavity is provided with an exhaust outlet I communicated with indoor air and an exhaust outlet II communicated with external air, and a fan III is installed in the exhaust cavity.

10. A buried air conditioning system according to any one of claims 1 to 9 wherein said air communication means and said air delivery means are fixedly mounted within a wall surface.

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