CN114234291A - Floor type air conditioner indoor unit, control method thereof and air conditioner - Google Patents

Abstract

The invention discloses a floor type air conditioner indoor unit, a control method thereof and an air conditioner, wherein the floor type air conditioner indoor unit comprises a host machine, a sub machine, an oxygen generation module and an ion generator; the main machine comprises an indoor heat exchange module; the sub machine is detachably connected with the main machine, and when the sub machine is separated from the main machine, the sub machine can independently work; the oxygen generation module is used for generating oxygen; the ion generator is used for generating negative ions; wherein, the oxygen generation module and/or the ion generator are arranged on the submachine. The floor type air conditioner indoor unit enables the negative oxygen ion generating area to be flexibly changed, and can improve the concentration of the negative oxygen ions at the position of a user in real time, so that the air freshness of the position of the user is improved, the actual using effect of the negative oxygen ions is improved to the maximum extent, and the breathing environment of the user is improved.

Description

Floor type air conditioner indoor unit, control method thereof and air conditioner

Technical Field

The invention relates to the technical field of air conditioning, in particular to a floor type air conditioner indoor unit, a control method thereof and an air conditioner.

Background

The negative oxygen ion refers to oxygen ion with negative charge, and is colorless and odorless. The negative oxygen ion known as 'air vitamin' is beneficial to the physical and mental health of human body. Some current air conditioners are added with a negative oxygen ion function, and in the current negative oxygen ion preparation schemes, the scheme adopted is generally that negative ions and oxygen are simultaneously generated in a fixed area and released to the fixed area.

The disadvantages of these solutions are that the negative oxygen ion generating area is fixed, the release position cannot be changed, etc., and when the user moves and changes the position, the practical use effect of the negative oxygen ion is greatly reduced due to the limitation of the negative oxygen ion diffusion.

The above is only for the purpose of assisting understanding of the technical solutions of the present invention, and does not represent an admission that the above is the prior art.

Disclosure of Invention

The invention mainly aims to provide a floor type air conditioner indoor unit, and aims to solve the technical problem that the actual use effect of negative oxygen ions of the floor type air conditioner indoor unit is poor.

In order to achieve the purpose, the floor type air conditioner indoor unit provided by the invention comprises a host machine, a sub machine, an oxygen generation module and an ion generator;

the main machine comprises an indoor heat exchange module;

the sub machine is detachably connected with the main machine, and when the sub machine is separated from the main machine, the sub machine can independently work;

the oxygen generation module is used for generating oxygen;

the ion generator is used for generating negative ions;

wherein the oxygen generation module and/or the ion generator are/is arranged on the submachine.

In an embodiment, the floor type air conditioner indoor unit further includes a human body detection device for detecting activity information of a human body, the human body detection device is disposed on the host machine and/or the sub-machine, and the ion generator and/or the oxygen generation module adjust the concentration of negative oxygen ions in an area where the human body is located according to the activity information of the human body.

In one embodiment, the human body detection device comprises one or more of a human body infrared sensor, a TOF sensor and a radar sensor, and the activity information of the human body comprises one or more of the number of people, the position of the human body and the movement displacement of the human body.

In one embodiment, the human body detection device is mounted on the upper part of the host machine.

In an embodiment, the sub-machine further includes a control device and a mobile device, and the control device is connected to the human body detection device for controlling the mobile device to drive the sub-machine to move to an area where a human body is located.

In one embodiment, the ion generator is an anion module, the submachine is provided with the anion module, and the main frame is provided with the oxygen generation module.

In one embodiment, the floor type air conditioner indoor unit further comprises a fresh air device, the fresh air device is mounted on the host, and the fresh air device is provided with a fresh air inlet communicated with the outside, a fresh air outlet communicated with the inside and a fresh air duct communicated with the fresh air inlet and the fresh air outlet; the air inlet of the oxygen generation module is communicated with the fresh air duct, and/or the waste gas outlet of the oxygen generation module is communicated with the fresh air inlet.

In one embodiment, the oxygen generation module is installed in the fresh air duct;

an oxygen outlet of the oxygen generation module is communicated with the fresh air outlet; or the like, or, alternatively,

an oxygen outlet of the oxygen generation module is communicated with an indoor air outlet of the main machine; or the like, or, alternatively,

the fresh air device is provided with an air inlet, and an oxygen outlet of the oxygen generation module is communicated with the indoor space through the air inlet.

In an embodiment, the fresh air device comprises a fresh air casing and a filter screen, the fresh air duct is formed in the fresh air casing, the fresh air outlet is formed in the fresh air casing, the filter screen is installed in the fresh air duct and corresponds to the fresh air outlet, the oxygen generation module is provided with a heat dissipation opening, and the heat dissipation opening faces the filter screen.

In an embodiment, the fresh air outlet is disposed on both opposite sides of the fresh air casing, and the oxygen generation module has a heat sink corresponding to each of the fresh air outlets.

In one embodiment, the oxygen generation module releases oxygen towards the submachine.

In an embodiment, the submachine further comprises a submachine shell, the submachine shell is provided with an air inlet, an air outlet and an air treatment air duct communicating the air inlet and the air outlet, an air treatment module is arranged in the air treatment air duct, and the ion generator is installed at the air outlet of the submachine shell.

In an embodiment, the oxygen generation module includes an oxygen generation housing, a pump body and an oxygen-enriched membrane installed in the oxygen generation housing, the oxygen generation housing is provided with an air inlet, an oxygen outlet and a waste gas outlet, the pump body is used for driving air to enter the oxygen-enriched membrane from the air inlet, the oxygen is blown out from the oxygen outlet after oxygen is formed, and the waste gas is blown out from the waste gas outlet after waste gas is formed.

In an embodiment, the floor type air conditioner indoor unit further includes a carbon dioxide sensor, the carbon dioxide sensor is used for detecting the gas concentration of indoor carbon dioxide, and the sub unit and/or the main unit is provided with the carbon dioxide sensor.

The invention also provides an air conditioner, which comprises an air conditioner outdoor unit and a floor type air conditioner indoor unit which are communicated through a refrigerant pipe, wherein the floor type air conditioner indoor unit comprises a host machine, a sub machine, an oxygen generation module and an ion generator;

the main machine comprises an indoor heat exchange module;

the sub machine is detachably connected with the main machine, and when the sub machine is separated from the main machine, the sub machine can independently work;

the oxygen generation module is used for generating oxygen;

the ion generator is used for generating negative ions;

wherein the oxygen generation module and/or the ion generator are/is arranged on the submachine.

The invention also provides a control method of the floor type air-conditioning indoor unit, wherein the floor type air-conditioning indoor unit is the floor type air-conditioning indoor unit in the embodiment of the invention, the floor type air-conditioning indoor unit has an oxygen generation mode and a fresh air mode, when the floor type air-conditioning indoor unit is in the oxygen generation mode, the oxygen generation module generates oxygen from outdoor air and sends the oxygen to the indoor, and when the floor type air-conditioning indoor unit is in the fresh air mode, outdoor fresh air is introduced into the indoor, and the control method of the floor type air-conditioning indoor unit comprises the following steps:

acquiring the concentration of indoor carbon dioxide gas through a carbon dioxide sensor;

determining that the concentration of the indoor carbon dioxide gas is greater than a preset concentration value, and starting an oxygen generation mode and a fresh air mode;

and determining that the concentration of the indoor carbon dioxide gas is less than a preset concentration value, and starting an oxygen generation mode or a fresh air mode.

According to the floor type air conditioner indoor unit, the host machine comprises the indoor heat exchange module, the sub machine is detachably connected to the host machine, and when the sub machine is separated from the host machine, the sub machine can work independently; and the oxygen generation module and/or the ionizer are/is mounted on the submachine. The generation area of the negative oxygen ions is changed by moving the sub machine, when a user walks and changes the position, the sub machine can be moved to the position of the user, the negative oxygen ions can be released to the area of the user, the concentration of the negative oxygen ions at the position of the user is improved, the air freshness of the position of the user is improved, the actual use effect of the negative oxygen ions is improved to the maximum extent, and the breathing environment of the user is improved. Compared with the mode of moving the whole floor type air conditioner indoor unit, the sub-unit can be moved more flexibly and conveniently, so that different use requirements of users can be met.

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 following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural view of a floor type air conditioner indoor unit according to an embodiment of the present invention;

FIG. 2 is a schematic view of the structure of the floor-type indoor unit of the air conditioner shown in FIG. 1, in which the sub-unit is separated from the main unit;

FIG. 3 is a schematic view of a partial structure of a sub-unit of the floor type air conditioner indoor unit according to an embodiment of the present invention;

FIG. 4 is a schematic view of a sub-unit of a floor type air conditioner indoor unit according to another embodiment of the present invention;

FIG. 5 is a schematic view of another embodiment of a floor type air conditioner indoor unit according to the present invention;

FIG. 6 is a schematic structural view of a fresh air device of a floor type air conditioner indoor unit according to an embodiment of the present invention;

FIG. 7 is a schematic cross-sectional view of the fresh air device of FIG. 6;

FIG. 8 is a schematic structural view of an oxygen generation module of a floor type air conditioner indoor unit according to an embodiment of the present invention;

fig. 9 is a flowchart illustrating a control method for a floor type air conditioner indoor unit according to an embodiment of the present invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)	Reference numerals	Name (R)
						100	Main unit	310	Air inlet	610	Fresh air inlet
200	Sub machine	320	Oxygen outlet	620	Fresh air outlet
						210	Mobile device	330	Heat dissipation port	630	Fresh air duct
220	Sub-machine shell	340	Pump body	640	Fresh air shell
						221	Air inlet	350	Oxygen-enriched membrane	650	Filter screen
222	Air outlet	400	Ion generator	700	Carbon dioxide sensor
						223	Air treatment air duct	500	Human body detection device
300	Oxygen generation module	600	Fresh air device

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be noted that if the description of "first", "second", etc. is provided in the embodiment of the present invention, the description of "first", "second", etc. is only for descriptive purposes and is not to be construed as indicating or implying relative importance or implicitly indicating the number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout is to include three juxtapositions, exemplified by "A and/or B" including either scheme A, or scheme B, or a scheme in which both A and B are satisfied.

The invention provides a floor type air conditioner indoor unit.

In the embodiment of the present invention, as shown in fig. 1 to 7, the floor type air conditioner indoor unit includes a main unit 100, a sub-unit 200, an oxygen generation module 300, and an ion generator 400, and the main unit 100 includes an indoor heat exchange module. The sub-unit 200 is detachably connected to the main unit 100, and the sub-unit 200 can operate independently when the sub-unit 200 is detached from the main unit 100. The oxygen generation module 300 is used to generate oxygen; the ionizer 400 is used to generate negative ions. Wherein the oxygen generation module 300 and/or the ionizer 400 are mounted on the sub-machine 200.

In the present embodiment, the overall shapes of the master unit 100 and the slave unit 200 may be cylindrical, elliptic cylindrical, square cylindrical, or other shapes, and the shapes of the master unit 100 and the slave unit 200 may be the same or different. The selection and design can be specifically carried out according to the actual use requirements, and the method is not limited herein. Optionally, the cross section of the housing is rectangular. So for the whole square column shape setting that is of submachine 200, then the arrangement of the inside air treatment module isotructure of submachine 200 is compacter, and then reduces the volume and the occupation space of submachine 200. The main unit 100 and the sub unit 200 extend in the vertical direction as a whole, and the main unit 100 and the sub unit 200 may be arranged in the vertical direction with a uniform cross section or a variable cross section. The indoor heat exchange module is provided with a heat exchange air duct, and an air treatment air duct 223 is formed in the submachine 200. When the slave unit 200 is connected to the master unit 100, the heat exchange duct and the air treatment duct 223 may be isolated from each other or may be connected to each other. In practice, when the sub-unit 200 is connected to the main unit 100, the heat exchange duct and the air treatment duct 223 are isolated from each other. Thus, the heat exchange air duct and the air treatment air duct 223 are independent from each other and do not affect each other, so that the heat exchange effect of the indoor heat exchange module is not affected when the sub-machine 200 is connected with and separated from the main machine 100, and the heat exchange stability of the whole floor type air conditioner indoor machine is ensured.

The indoor heat exchange module is used for exchanging heat for the air flow passing through the heat exchange air duct so as to realize refrigeration or heating. The indoor heat exchange module can only have a refrigerating function and can also have a refrigerating function and a heating function. It can be understood that the main unit 100 further includes a heat exchange air inlet and a heat exchange air outlet communicated with the heat exchange air duct. The heat exchange assembly is arranged in the heat exchange air duct and comprises a heat exchanger and a heat exchange fan, the heat exchange fan drives airflow to enter the heat exchange air duct from the heat exchange air inlet and blow out from the heat exchange air outlet after heat exchange of the heat exchanger, and therefore indoor refrigeration or heating is achieved. The indoor heat exchange module further comprises a refrigerant pipe, a compressor and other structures, and the specific structure of the indoor heat exchange module can refer to the existing technology of the floor type air conditioner indoor unit and is not described herein again.

The sub-unit 200 is detachably connected to the main unit 100, and the sub-unit 200 can be connected to the inside of the main unit 100, for example, an accommodating cavity is provided in the main unit 100, so that the sub-unit 200 is installed in the accommodating cavity, and the accommodating cavity can be located at the upper part, the middle part or the lower part of the main unit 100. The sub-unit 200 can also be connected to the outside of the main unit 100, such as the bottom, top, peripheral side, etc. of the main unit 100. The connection between the sub-unit 200 and the main unit 100 can be a structural connection, such as a snap connection, a magnetic connection, or an insertion connection. It can be understood that the sub-machine 200 can be detached from the main machine 100 by the user's manual detachment, and the control device can control the sub-machine 200 to be actively detached from the main machine 100 without the user's manual operation. When the sub-machine 200 is detached from the main machine 100, the sub-machine 200 can operate independently, that is, the sub-machine 200 has an independent power supply, and power can be supplied to the sub-machine 200 by using a storage battery or a direct-plug power supply, so as to realize the independent operation of the sub-machine 200. When the sub-unit 200 is mounted to the main unit 100, the sub-unit 200 is powered by the main unit 100, and the circuit between the main unit 100 and the sub-unit 200 can be conducted by a power connection electrode plate, a charging module, or the like.

When the sub-unit 200 is separated from the main unit 100, the sub-unit 200 can move in a circulating manner in the room to meet the requirement of the whole indoor air treatment and ensure that the air supply of the whole space is uniform. The user can move the sub-machine 200 to an indoor required position or independently move the sub-machine 200 to a certain position, such as a multi-user concentrated area, through manual movement, so that fixed-point air supply in a certain area can be met, long-distance, fixed-point and directional air supply is realized, and the air treatment effect is improved. Compared with the method for moving the whole floor type air conditioner indoor unit, the sub-unit 200 can be moved more flexibly and conveniently, so that different use requirements of users can be met. And the sub-machine 200 can carry out relay air supply on the airflow blown out from the heat exchange air outlet of the main machine 100, so that the air supply distance is longer and the air supply range is wider.

Oxygen generation module 300 can produce oxygen by hydrolysis, such that oxygen generation module 300 is an electrolytic water oxygen generator. Oxygen generation module 300 can also produce oxygen by separating air, such as making oxygen generation module 300 an air separation oxygen generator. Of course, oxygen generation module 300 can also generate oxygen in other ways, and is not limited in this regard. The ionizer 400 may be specifically an anion generator 400, and the anion generator 400 includes a needle-tip electrode through which high-voltage ionized air is output to generate anions. The ion generator 400 may be of various types, and only needs to be capable of generating enough negative ions, and is not particularly limited herein. Oxygen is generated through the oxygen generation module 300, and the ion generator 400 generates negative ions, so that the negative ions are combined with the oxygen to form negative oxygen ions, and the negative oxygen ions are beneficial to physical and psychological health of a human body.

Only the oxygen generation module 300 or the ionizer 400 may be mounted on the sub-machine 200, or the oxygen generation module 300 and the ionizer 400 may be mounted on the sub-machine 200 at the same time. Specifically, the ion generator 400 is an anion module, the submachine 200 is provided with an anion module, and the main machine 100 is provided with an oxygen generation module 300. In some embodiments, oxygen generation module 300 can also be placed on an outdoor unit such that only oxygen outlet 320 of oxygen generation module 300 is in communication with the room. Thus, the generating area of the negative oxygen ions can be changed by moving the sub-unit 200, so that the generating area of the negative oxygen ions in the space can be adjusted. The user can move the sub-machine 200 manually or remotely, and the sub-machine 200 can be detected autonomously and moved to a required position. Therefore, when the user walks and changes the position, the submachine 200 can be moved to the position of the user, negative oxygen ions can be released in the area of the user, the concentration of the negative oxygen ions at the position of the user is improved, the air freshness of the position of the user is improved, and the effect of improving the breathing environment of the user to the maximum extent is achieved.

According to the floor type air conditioner indoor unit, the main unit 100 comprises the indoor heat exchange module, the sub machine 200 is detachably connected to the main unit 100, and when the sub machine 200 is separated from the main unit 100, the sub machine 200 can work independently; and the oxygen generation module 300 and/or the ionizer 400 are mounted on the sub-machine 200. The generation area of the negative oxygen ions is changed by moving the sub-machine 200, and when the user walks and changes the position, the sub-machine 200 can be moved to the position of the user, so that the negative oxygen ions can be released to the area of the user, the concentration of the negative oxygen ions at the position of the user is improved, the air freshness of the position of the user is improved, the actual use effect of the negative oxygen ions is improved to the maximum extent, and the breathing environment of the user is improved. Compared with the method for moving the whole floor type air conditioner indoor unit, the sub-unit 200 can be moved more flexibly and conveniently, so that different use requirements of users can be met.

In an embodiment, referring to fig. 5, the floor type air conditioner indoor unit further includes a human body detection device 500, the human body detection device 500 is used for detecting activity information of a human body, the human body detection device 500 is disposed on the host machine 100 and/or the sub-machine 200, and the ion generator 400 and/or the oxygen generation module 300 adjusts the negative oxygen ion concentration of the area where the human body is located according to the activity information of the human body.

It can be understood that the floor type air conditioner indoor unit further comprises a control device, the human body detection device 500 can detect human body activity information and send the human body activity information to the control device, and the control device controls the ion generator 400 and the oxygen generation module 300 to adjust the negative oxygen ion concentration of the area where the human body is located according to the human body activity information. Specifically, the oxygen generation concentration and the oxygen generation flow of the oxygen generation module 300 can be adjusted by controlling the oxygen generation module 300 to supply air to the area where the human body is located. The anion generator 400 can be controlled to send anions to the region where the human body is located, the anion generating concentration and the anion generating efficiency are improved, the anion concentration of the region where the human body is located is adjusted, and the negative oxygen ion concentration of the region where the human body is located is adjusted. Of course, on the premise that the sub-machine 200 can move autonomously, the sub-machine 200 can be controlled to move to the area where the human body is located, so that the concentration of the negative oxygen ions in the area where the human body is located is increased. Make ion generator 400 and/or system oxygen module 300 adjust the regional negative oxygen ion concentration in human body according to human activity information, then can realize real-time detection human activity information to guarantee that the regional negative oxygen ion concentration in human body can reach the requirement always, realize intelligent control, promote user's use and experience.

Specifically, the human body detection device 500 includes one or more of a human body infrared sensor, a TOF sensor, and a radar sensor, and the activity information of the human body includes one or more of the number of people, the position of the human body, and the movement displacement of the human body. The human body infrared sensor can be specifically a thermopile type sensor or a pyroelectric type sensor. Different human detection devices 500 may be selected according to the actually required human activity information. Detect the number of people through human detection device 500, human position, human removal displacement, then can be with this information transmission to controlling means, controlling means is according to this human activity information control ion generator 400 and system oxygen module 300 towards human region of place or the regional release negative oxygen ion of activity, and can adjust the regional negative oxygen ion concentration in human region of place according to the number of people, thereby make the system negative oxygen ion function of floor type air conditioner indoor set humanized and intelligent more, greatly promoted user and used experience.

Further, as shown in fig. 5, the human body detecting device 500 is installed at an upper portion of the main unit 100. It will be appreciated that the size of the master unit 100 is generally larger than the size of the slave unit 200. The human body detection device 500 is installed at the upper portion of the main body 100, so that the installation height of the human body detection device 500 is higher than that of the main body 100, and the detection range of the human body detection device 500 can be enlarged. Of course, in order to improve the detection accuracy, the human body detection device 500 may also be installed on the sub-unit 200, and the detection data of the human body detection device and the sub-unit may be used to obtain more accurate and precise information.

In an embodiment, as shown in fig. 2 to 5, the sub-machine 200 includes a control device and a moving device 210, and the control device is connected to the human body detection device 500 for controlling the moving device 210 to drive the sub-machine 200 to move to an area where a human body is located.

In this embodiment, the mobile device 210 may specifically be a driving wheel with a universal wheel, a roller with a turntable, etc., and the mobile device 210 can drive the sub-machine 200 to move and turn, thereby realizing multi-directional movement in the whole room. The control device may be specifically installed on or in the housing of the sub-machine 200, and then the user may send a signal to the control device in a wireless transmission mode or an infrared remote control mode, so as to control the movement of the mobile device 210. A program may be written in the control main board, so that the sub-machine 200 moves autonomously. It can be understood that the sub-machine 200 can be controlled to move in real time by remote control of a remote controller, remote control of a mobile phone APP, or the like, or the moving position, time, moving path, and the like of the sub-machine 200 are preset. The obstacle avoidance sensors such as the infrared sensor and the ultrasonic sensor can be arranged on the sub-machine 200, so that the sub-machine 200 can autonomously avoid obstacles, turn to move, and control the sub-machine 200 to have multiple action modes, and therefore the sub-machine 200 is equivalent to an air conditioning robot, the moving direction can be adjusted according to the feedback of the indoor environment, the walking route can be autonomously planned, and the sub-machine 200 can be ensured to avoid obstacles and walk flexibly.

The control device is connected with the human body detection device 500 for receiving the human body activity information detected by the human body detection device 500. The control device can then control the mobile device 210 to drive the sub-machine 200 to move to the area where the human body is located according to the activity information of the human body. And the moving position of the sub-machine 200 can be adjusted in real time according to the activity information of the human body, so that the negative oxygen ions can be released in the area where the human body is located. The temperature, humidity, or pollutant sensor may be provided in the sub-unit 200, so that the sub-unit 200 can detect an environmental state in a certain area during movement, and thus it is possible to autonomously determine whether the sub-unit leaves or stays for continuous air supply. Of course, a visual sensor may be further disposed on the sub-machine 200, the indoor panoramic image is shot through the movement of the sub-machine 200 and uploaded to the cloud system, and then the user may observe the movement of the sub-machine 200 through a mobile phone, a tablet, a computer, and other intelligent devices at any time. Of course, the control device may be used to control the slave unit 200 to be detached from the master unit 100. Thus, the independent movement of the sub-machine 200 can be realized, and the automation is more realized.

In practical applications, the sub-machine 200 further has a power supply, and the power supply includes a storage battery and a charging module, the storage battery is used for storing electric energy of the charging module, and is connected with the control device. The charging module can be a wireless charging module, a power connection electrode plate, a direct-flushing type charging module and the like. Wireless charging, contact charging, or charging by prompting the user, etc. can be realized after the electric quantity of the sub-machine 200 is insufficient. The sub-unit 200 can automatically return to the main unit 100 for charging, or can be additionally provided with a charging seat for charging, so that the sub-unit 200 can be automatically positioned and moved to be connected with the charging seat for charging through the positioning device. The electric energy is stored in the storage battery, and the sub-machine 200 can continuously work after being charged, and has long endurance time and good endurance capacity.

In combination with the above-mentioned embodiment in which the ion module is disposed on the sub-machine 200 and the oxygen generation module 300 is disposed on the main machine 100, referring to fig. 5 to 7, the floor type air conditioner indoor unit further includes a fresh air device 600, the fresh air device 600 is mounted on the main machine 100, the fresh air device 600 has a fresh air inlet 610 communicated with the outside, a fresh air outlet 620 communicated with the inside, and a fresh air duct 630 communicating the fresh air inlet 610 and the fresh air outlet 620; the air inlet 310 of the oxygen generation module 300 is communicated with the fresh air duct 630, and/or the exhaust outlet of the oxygen generation module 300 is communicated with the fresh air inlet 610.

In this embodiment, a fresh air blower may be further disposed in the fresh air device 600, so as to drive outdoor airflow to enter the fresh air duct 630 through the fresh air inlet 610, and to be blown out through the fresh air outlet 620. Oxygen generation module 300 can be installed in fresh air duct 630, also can install outside fresh air duct 630, only need make oxygen generation module 300's air inlet 310 and fresh air duct 630 intercommunication can. The air inlet 310 of the oxygen generation module 300 can be specifically communicated with the fresh air duct 630 through a rubber hose. Through making oxygen module 300's air inlet 310 and new trend wind channel 630 intercommunication, then oxygen module 300 can make oxygen to the new trend to improve the oxygen content of new trend, make the new trend of introducing indoor more fresh, promote the new trend comfort level. The exhaust outlet of oxygen generation module 300 communicates with fresh air inlet 610 to exhaust the exhaust gas that oxygen generation module 300 produced to outdoor, then make full use of fresh air inlet 610 need not set up the exhaust outlet in addition and discharge the exhaust gas of oxygen generation module 300. Of course, in other embodiments, the exhaust outlet of oxygen generation module 300 can be communicated with the outside of the room through an additional opening.

In one embodiment, referring to fig. 7, oxygen generation module 300 is installed in fresh air duct 630;

the oxygen outlet 320 of the oxygen generation module 300 is communicated with the fresh air outlet 620; or the like, or, alternatively,

an oxygen outlet 320 of the oxygen generation module 300 is communicated with an indoor air outlet of the main machine 100; or the like, or, alternatively,

the fresh air device 600 is provided with an air passing port, and the oxygen outlet 320 of the oxygen generation module 300 is communicated with the indoor space through the air passing port.

In this embodiment, the oxygen generation module 300 is installed in the fresh air duct 630, so as to make full use of the space in the fresh air device 600, and make the overall structure of the main unit 100 more compact. The shape and size of oxygen generation module 300 can be designed according to the size and shape of fresh air duct 630 and is not specifically limited herein. One oxygen generation module 300 can be arranged in the fresh air duct 630, and two or more oxygen generation modules 300 can be arranged and can be selected according to actual use requirements. Make oxygen module 300's oxygen outlet 320 and new trend export 620 intercommunication, then the oxygen that accessible oxygen module 300 made blows out to indoor through new trend export 620, need not set up in addition the oxygen outlet 320 intercommunication of process and oxygen module to send oxygen to indoor. Make oxygen module 300's oxygen outlet 320 and the indoor air outlet intercommunication of host computer 100, then usable host computer 100's indoor air outlet to make the oxygen scope that oxygen module 300 blew out wider, and easily control the direction of the oxygen that oxygen module 300 blew out. And the oxygen outlet 320 of the oxygen generation module 300 is communicated with the indoor through the air passing opening, so that the oxygen generated by the oxygen generation module 300 can be directly released to the indoor, and the oxygen delivery capacity is improved.

In an embodiment, as shown in fig. 6 and 7, the fresh air device 600 includes a fresh air housing 640 and a filter screen 650, a fresh air duct 630 is formed in the fresh air housing 640, a fresh air outlet 620 is formed on the fresh air housing 640, the filter screen 650 is installed in the fresh air duct 630 and is disposed corresponding to the fresh air outlet 620, the oxygen generation module 300 has a heat dissipation opening 330, and the heat dissipation opening 330 is disposed toward the filter screen 650.

In this embodiment, in order to facilitate cleaning and replacement of the filter screen 650, the filter screen 650 may be detachably mounted on the fresh air housing 640. Particularly, the filter screen 650 can be mounted and dismounted in a drawing mode, so that the operation of a user is facilitated. Filter screen 650 specifically can be the HEPA net, filters the new trend through filter screen 650 to guarantee to introduce indoor new trend quality. It is understood that oxygen generation module 300 generates a certain amount of heat when producing oxygen, such that the heat is blown out through heat sink 330. Through making thermovent 330 of system oxygen module 300 set up towards filter screen 650, make hot-air current can play the effect of disinfecting to filter screen 650, and then effectively restrain and breed the bacterium on filter screen 650, ensure user's health and safety.

Further, fresh air outlet 620 has all been seted up to the relative both sides face of fresh air casing 640, and system oxygen module 300 has seted up a thermovent 330 corresponding to each fresh air outlet 620. Therefore, the fresh air outlets 620 are formed in the two side faces of the fresh air shell 640, and the fresh air inlet volume can be effectively increased. Each fresh air outlet 620 is correspondingly provided with a filter screen 650, so that the oxygen generation module 300 is provided with two heat dissipation ports 330 which respectively face the filter screens 650 at two sides, and the filter screens 650 can be effectively sterilized. A fresh air blower may be provided corresponding to each fresh air outlet 620. To promote new trend efficiency.

In one embodiment, the oxygen generation module 300 releases oxygen towards the sub-machine 200. It can be understood that the direction of the oxygen outlet 320 of the oxygen generation module 300 can be adjusted by making the direction of the oxygen outlet 320 of the oxygen generation module 300 adjustable, so that the oxygen generation module 300 releases oxygen towards the sub-machine 200. Of course, under the condition that the oxygen outlet 320 of the oxygen generation module 300 is communicated with the indoor air outlet of the main unit 100, the oxygen generation module 300 can release oxygen towards the sub-unit 200 by controlling the air outlet direction of the indoor air outlet. By making the oxygen generation module 300 release oxygen toward the sub-machine 200, the negative ion generator 400 on the sub-machine 200 can combine with sufficient oxygen to generate beneficial negative oxygen ions after releasing negative ions.

In one embodiment, as shown in fig. 3 and 4, the sub-machine 200 further includes a sub-machine 200 housing, the sub-machine 200 housing has an air inlet 221, an air outlet 222 and an air treatment duct 223 communicating the air inlet 221 and the air outlet 222, an air treatment module is disposed in the air treatment duct 223, and the ion generator 400 is mounted at the air outlet 222 of the sub-machine 200 housing.

In this embodiment, the air processing module may specifically include one or more of a purification module, a fragrance module, a humidification module, an electrolyzed water module, a deodorization module, and an allergen removal module, so that the sub-machine 200 has different air processing functions. The air treatment duct 223 is further provided with a fan therein for driving an air flow to enter the air treatment duct 223 from the air inlet 221, and to be blown out from the air outlet 222 after being treated by the air treatment module. By installing the ion generator 400 at the air outlet 222 of the chassis of the sub-machine 200, the negative ions can be blown out along with the airflow at the air outlet 222 of the sub-machine 200, thereby increasing the release rate of the negative ions.

Specifically, referring to fig. 7 and 8, the oxygen generation module 300 includes an oxygen generation housing, a pump 340 and an oxygen-enriched membrane 350 installed in the oxygen generation housing, the oxygen generation housing is provided with an air inlet 310, an oxygen outlet 320 and a waste gas outlet, the pump 340 is used for driving air to enter the oxygen-enriched membrane 350 from the air inlet 310, and after oxygen is formed, the air is blown out from the oxygen outlet 320, and after waste gas is formed, the air is blown out from the waste gas outlet. The pump body 340 may be a vacuum pump. The pump body 340 drives air to enter the oxygen making housing from the air inlet 310, and then the air is filtered by the oxygen enrichment membrane 350, because the oxygen enrichment membrane 350 makes the permeation rate of each component in the air when permeating the membrane different, under the driving of pressure difference, oxygen in the air preferentially passes through the membrane to obtain oxygen-enriched air, and blows out the oxygen-enriched air through the oxygen outlet 320, and the residual air after filtering blows out through the waste gas outlet. In other embodiments, the pump body 340 may also be a compressor.

In an embodiment, referring to fig. 4, the floor type air conditioning indoor unit further includes a carbon dioxide sensor 700, the carbon dioxide sensor 700 is used for detecting the gas concentration of the indoor carbon dioxide, and the sub unit 200 and/or the main unit 100 is provided with the carbon dioxide sensor 700. Through setting up the gas concentration that carbon dioxide sensor 700 detected indoor carbon dioxide, then can indirectly obtain oxygen concentration in the air, and then can judge whether need open system oxygen module 300. The carbon dioxide sensor 700 may be provided at any position of the main unit 100 or the sub unit 200, and only needs to be able to effectively detect the concentration of carbon dioxide in the air. In the embodiment where the carbon dioxide sensor 700 is installed on the sub-machine 200, the carbon dioxide sensor 700 may be installed in the enclosure of the sub-machine 200, and the enclosure of the sub-machine 200 is provided with an air inlet of the carbon dioxide sensor, so as to accurately detect the concentration of carbon dioxide in the air. Preferably, the sub-unit 200 is provided with a carbon dioxide sensor 700. The air quality condition in the room can be detected more thoroughly because the shells of the sub-machines 200 move all around.

The invention further provides an air conditioner, which comprises an air conditioner outdoor unit and a floor type air conditioner indoor unit which are communicated through a refrigerant pipe, the specific structure of the floor type air conditioner indoor unit refers to the embodiments, and the air conditioner adopts all the technical schemes of all the embodiments, so that the air conditioner at least has all the beneficial effects brought by the technical schemes of the embodiments, and the details are not repeated.

The invention also provides a control method of the floor type air-conditioning indoor unit, which is applied to the floor type air-conditioning indoor unit of the embodiment, in an embodiment, as shown in fig. 9, the floor type air-conditioning indoor unit has an oxygen generation mode and a fresh air mode, when the floor type air-conditioning indoor unit is in the oxygen generation mode, the oxygen generation module 300 generates oxygen from outdoor air and sends the oxygen into the room, and when the floor type air-conditioning indoor unit is in the fresh air mode, outdoor fresh air is introduced into the room, the control method of the floor type air-conditioning indoor unit provided by the invention comprises the following steps:

step S10, acquiring the concentration of carbon dioxide gas in the room by the carbon dioxide sensor 700;

step S20, determining that the concentration of the indoor carbon dioxide gas is greater than a preset concentration value, and starting an oxygen generation mode and a fresh air mode;

and step S30, determining that the concentration of the indoor carbon dioxide gas is less than a preset concentration value, and starting an oxygen generation mode or a fresh air mode.

In this embodiment, since the carbon dioxide content in the air is only 0.03% and the oxygen content is 20.9%, when the oxygen content in the air is changed, the fluctuation of the oxygen concentration is very small and the fluctuation of the carbon dioxide concentration is very significant. Therefore, the carbon dioxide sensor 700 can easily determine the change in the oxygen content in the air by detecting the carbon dioxide concentration. When the concentration of the indoor carbon dioxide gas is greater than the preset concentration value, the carbon dioxide content in the air is high, and the oxygen concentration is low, so that an oxygen generation mode and a fresh air mode need to be started, the indoor air is rapidly oxygenated, and the freshness of the indoor air is further ensured. When the concentration of the indoor carbon dioxide gas is less than the preset concentration value, the oxygen content in the air is enough, and one of the oxygen making mode and the fresh air mode can be started at the moment so as to realize the slow and stable adjustment of the oxygen content in the air and ensure the continuous and fresh indoor air. It can be appreciated that since the power of oxygen generation module 300 is less than the power of fresh air device 600, oxygen generation module 300 can be preferably turned on to save energy consumption of the air conditioner. The carbon dioxide concentration is used as a detection control signal of the indoor unit of the floor type air conditioner, the opening, the running, the closing and the like of the oxygen generation function are controlled, and the floor type air conditioner is very practical, convenient and easy to control.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (16)

1. A floor type air conditioner indoor unit is characterized by comprising:

the main machine comprises an indoor heat exchange module;

the sub machine is detachably connected with the main machine, and can independently work when the sub machine is separated from the main machine;

the oxygen generation module is used for generating oxygen;

an ion generator for generating negative ions;

wherein the oxygen generation module and/or the ion generator are/is arranged on the submachine.

2. The indoor unit of floor type air conditioner as claimed in claim 1, further comprising a human body detecting device for detecting activity information of a human body, wherein the human body detecting device is provided on the host machine and/or the sub machine, and the ion generator and/or the oxygen generating module adjust the concentration of negative oxygen ions in an area where the human body is located according to the activity information of the human body.

3. The floor type air conditioner indoor unit as claimed in claim 2, wherein the human body detecting means comprises one or more of a human body infrared sensor, a TOF sensor, and a radar sensor, and the activity information of the human body comprises one or more of a number of people, a position of the human body, and a movement displacement of the human body.

4. The floor type air conditioner indoor unit as claimed in claim 2, wherein the human body detecting means is installed at an upper portion of the main unit.

5. The floor type air conditioner indoor unit as claimed in claim 2, wherein the sub-unit further comprises a control device and a moving device, the control device is connected with the human body detection device for controlling the moving device to drive the sub-unit to move to the area where the human body is located.

6. The indoor unit of a floor type air conditioner as claimed in any one of claims 1 to 5, wherein the ion generator is an anion module, the anion module is provided on the sub-unit, and the oxygen generation module is provided on the main unit.

7. The floor type air-conditioning indoor unit as claimed in claim 6, further comprising a fresh air device, the fresh air device being installed in the main unit, the fresh air device having a fresh air inlet communicating with the outside, a fresh air outlet communicating with the inside, and a fresh air duct communicating the fresh air inlet and the fresh air outlet; the air inlet of the oxygen generation module is communicated with the fresh air duct, and/or the waste gas outlet of the oxygen generation module is communicated with the fresh air inlet.

8. The floor type air-conditioning indoor unit of claim 7, wherein the oxygen generation module is installed in the fresh air duct;

an oxygen outlet of the oxygen generation module is communicated with the fresh air outlet; or the like, or, alternatively,

an oxygen outlet of the oxygen generation module is communicated with an indoor air outlet of the main machine; or the like, or, alternatively,

the fresh air device is provided with an air inlet, and an oxygen outlet of the oxygen generation module is communicated with the indoor space through the air inlet.

9. The indoor unit of a floor type air conditioner according to claim 8, wherein the fresh air device includes a fresh air casing and a filter screen, the fresh air duct is formed in the fresh air casing, the fresh air outlet is formed in the fresh air casing, the filter screen is installed in the fresh air duct and corresponds to the fresh air outlet, and the oxygen generation module has a heat dissipation opening facing the filter screen.

10. The indoor unit of a floor type air conditioner as claimed in claim 9, wherein the fresh air outlets are formed on two opposite sides of the fresh air casing, and the oxygen generation module is formed with one of the heat dissipation openings corresponding to each of the fresh air outlets.

11. The floor type air-conditioning indoor unit of claim 6, wherein the oxygen generation module releases oxygen toward the submachine.

12. The floor type air conditioner indoor unit as claimed in claim 1, wherein the sub-unit further comprises a sub-unit housing, the sub-unit housing has an air inlet, an air outlet and an air treatment duct communicating the air inlet and the air outlet, an air treatment module is disposed in the air treatment duct, and the ion generator is installed at the air outlet of the sub-unit housing.

13. The indoor unit of a floor type air conditioner as claimed in claim 1, wherein the oxygen generation module includes an oxygen generation housing, a pump body installed in the oxygen generation housing, and an oxygen enrichment membrane, the oxygen generation housing is provided with an air inlet, an oxygen outlet, and a waste gas outlet, the pump body is used for driving air to enter the oxygen enrichment membrane from the air inlet, and after oxygen is formed, the air is blown out from the oxygen outlet, and after waste gas is formed, the air is blown out from the waste gas outlet.

14. The floor type air conditioner indoor unit as claimed in claim 1, further comprising a carbon dioxide sensor for detecting a gas concentration of carbon dioxide in a room, wherein the sub unit and/or the main unit is provided with the carbon dioxide sensor.

15. An air conditioner comprising an outdoor unit of an air conditioner and an indoor unit of a floor type air conditioner as claimed in any one of claims 1 to 14.

16. A control method for a floor standing indoor air conditioner according to any one of claims 1 to 14, wherein the floor standing indoor air conditioner has an oxygen generation mode and a fresh air mode, the oxygen generation module of the floor standing indoor air conditioner generates oxygen from outdoor air and sends the oxygen to a room when the floor standing indoor air conditioner is in the oxygen generation mode, and outdoor fresh air is introduced into the room when the floor standing indoor air conditioner is in the fresh air mode, the control method for the floor standing indoor air conditioner comprises the following steps:

acquiring the concentration of indoor carbon dioxide gas through a carbon dioxide sensor;

determining that the concentration of the indoor carbon dioxide gas is greater than a preset concentration value, and starting an oxygen generation mode and a fresh air mode;

and determining that the concentration of the indoor carbon dioxide gas is less than a preset concentration value, and starting an oxygen generation mode or a fresh air mode.

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