WO2020082666A1 - Smart home system - Google Patents

Abstract

A smart home system, belonging to the technical field of air conditioning. The smart home system comprises immovable air conditioning devices and a movable air conditioner, and the smart home system executes the following steps by means of a control centre thereof: acquiring weather information, determining operation parameters of each air conditioning device according to the weather information, and controlling the operation of a corresponding air conditioning device according to the operation parameters of each air conditioning device. The present invention can be automatically adaptive to weather information, providing a better use experience to the user.

Description

A smart home system

This application is based on the Chinese patent application with the application number 201811246472.X and the application date of 2018-10-24, and claims the priority of the Chinese patent application. The entire content of the Chinese patent application is hereby incorporated by reference.

Technical field

The invention relates to the technical field of air conditioning, in particular to a smart home system.

Background technique

In a general use environment, the air conditioner adjusts the temperature in the entire enclosed space, and it is difficult to accurately adjust the temperature of each part in the enclosed space. The mobile air conditioner can be used to adjust the temperature of each part of the enclosed space. The mobile air conditioner is provided with a moving wheel at the bottom, and the mobile air conditioner is provided with an evaporator, evaporating fan, compressor, condenser, condensing fan Throttling elements, etc., in a smart home system that includes a mobile air conditioner, the indoor environment is often adjusted according to the set air index. However, under different weather information, the indoor environment that the user feels comfortable also changes. Therefore, according to Setting the air index to adjust the indoor environment has been unable to meet user needs.

Summary of the invention

Embodiments of the present invention provide a smart home system that can automatically adapt to weather information and provide users with a better experience.

In order to have a basic understanding of some aspects of the disclosed embodiments, a brief summary is given below. This summary is not a general comment, nor is it to determine key / important elements or to describe the scope of protection of these embodiments. Its sole purpose is to present some concepts in a simple form as a preface to the detailed description that follows.

According to a first aspect of the embodiments of the present invention, a smart home system is provided.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning devices include non-removable air-conditioning devices, and, mobile air conditioners;

The movable air conditioner includes:

A semiconductor temperature regulator, the first end of the semiconductor temperature regulator is used to exchange heat with an environmental medium, wherein the first end is any one of the cold and hot ends of the semiconductor temperature regulator; and,

A heat storage device, which is in contact with the second end of the semiconductor temperature regulator and used to exchange heat with the second end of the cold and hot ends of the semiconductor temperature regulator, wherein the second end is The other end of the cold end and the hot end of the semiconductor temperature regulator corresponding to the first end;

The smart home system performs the following steps through its control center:

Get weather information;

Determine the operating parameters of each air-conditioning device according to the weather information;

Control the operation of the corresponding air conditioning equipment according to the operating parameters of each air conditioning equipment.

In an optional implementation manner, the weather information includes one or more of temperature information, humidity information, and respirable particle concentration information.

In an optional embodiment, the operating parameters of the air-conditioning equipment include any one or more of a start / stop state, an adjustment function, an operating power, and an adjustment efficiency.

In an optional embodiment, the determining the operating parameters of each air-conditioning device according to the weather information includes:

Determine the comfortable air index according to the weather information;

The operating parameters of each air-conditioning device are determined according to the comfort air index.

In an optional embodiment, the movable air conditioner further includes:

The humidification device is connected to the heat storage device in the form of heat exchange. When the semiconductor temperature regulator is used for cooling, the heat storage device provides heat to the humidification device.

In an optional embodiment, the movable air conditioner further includes:

A mobile base, the lower part of the mobile base is provided with a rag for cleaning the ground, a water tank connected to the rag is provided on the base, and the water tank is used for supplying water to the rag;

The water storage unit of the humidification device communicates with the water tank through a conduit.

In an optional embodiment, the movable air conditioner further includes:

The heating chamber is connected to the heat storage device in the form of heat exchange, and when the semiconductor temperature regulator is used for cooling, the heat storage device provides heat to the heating device.

In an optional embodiment, the movable air conditioner further includes:

Air purification device for purifying respirable particles in indoor air.

In an optional embodiment, the movable air conditioner further includes:

Fresh air device for purifying carbon dioxide in indoor air.

In an optional embodiment, the movable air conditioner further includes:

A heat conduction device, a first portion of the heat conduction device is in contact with the second end of the semiconductor temperature regulator for heat exchange with the second end, and a second portion of the heat conduction device extends to the heat The interior of the storage device is used for heat exchange with the heat storage device;

When the heat conduction medium in the heat conduction device is a fluid, the fluid is driven by the heat of the second end of the semiconductor temperature regulator or the heat in the heat storage device, at the second end and the The heat storage device circulates back and forth.

The beneficial effects of the embodiments of the present invention are: in the smart home system, the operating parameters of each air-conditioning device are adjusted according to the weather information, which can automatically adapt to the weather information and provide users with a better experience.

It should be understood that the above general description and the following detailed description are only exemplary and explanatory, and do not limit the present invention.

BRIEF DESCRIPTION

The drawings herein are incorporated into and constitute a part of this specification, show embodiments consistent with the present invention, and are used to explain the principles of the present invention together with the specification.

Fig. 1 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 2 is a schematic diagram showing a principle of a semiconductor temperature regulator according to an exemplary embodiment;

Fig. 3 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 4 is a schematic structural diagram of a movable base according to an exemplary embodiment;

Fig. 5 is a schematic diagram showing a connection structure of a semiconductor temperature regulator and a heat storage device according to an exemplary embodiment;

6 is a schematic diagram showing a connection structure of a semiconductor temperature regulator and a heat storage device according to an exemplary embodiment;

Fig. 7 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 8 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 9 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 10 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 11 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 12 is a schematic structural diagram of an air conditioner including a cleaning device according to an exemplary embodiment;

Fig. 13 is a schematic structural diagram of a mobile base including a cleaning device according to an exemplary embodiment;

Fig. 14 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 15 is a schematic structural diagram of a smart home system according to an exemplary embodiment;

Fig. 16 is a schematic structural diagram of a smart home system according to an exemplary embodiment;

Fig. 17 is a schematic structural diagram of a mobile air conditioner according to an exemplary embodiment;

Fig. 18 is a schematic structural diagram of a refrigerant pipeline according to an exemplary embodiment;

Fig. 19 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Fig. 20 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Fig. 21 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Fig. 22 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Fig. 23 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Fig. 24 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Fig. 25 is a schematic diagram of a control flow of a smart home system according to an exemplary embodiment;

Description of drawings:

11. Semiconductor temperature regulator; 111, cold end; 112, hot end; 113, metal conductor; 114, semiconductor; 115, heat sink fins; 12, heat storage device; 121, first heat storage device; 122, second Heat storage device; 124, thermal insulation layer; 13, heat conduction device; 131, circulation pipeline; 1311, first part of pipeline; 1312, second part of pipeline; 1313, third part of pipeline; 1314, fluid buffer Bag; 14. Power supply device; 141, first power supply device; 142, second power supply device; 15, mobile base; 151, drive wheel; 152, drive motor; 153, guide wheel; 155, obstacle avoidance module; 17, rotor 171, first steering mechanism; 172, second steering mechanism; 21, detection device; 22, housing; 221, air inlet; 222, air outlet; 223, first upper housing; 224, first lower housing Body; 225, card protrusion; 226, card slot; 23, fan; 41, cleaning device; 411, side brush; 412, rolling brush; 413, dust box; 414, rag; 42, lifting mechanism; 51, humidification device; 511, atomizer; 512, vent; 513, vent valve; 514, catheter; 515, Water storage unit; 516, conduit valve; 52, heating chamber; 61, heat supply line; 62, heat exchange port; 63, heat replacement line; 64, first heat exchanger; 641, refrigerant input interface; 642 , Refrigerant output interface; 643, the first matching connector; 65, refrigerant supply pipeline; 651, refrigerant input pipeline; 652, refrigerant output pipeline; 653, supply output interface; 654, supply input interface; 655, second Matching connectors.

detailed description

The following description and the drawings sufficiently illustrate specific embodiments of the present invention to enable those skilled in the art to practice them. Parts and features of some embodiments may be included in or substituted for parts and features of other embodiments. The scope of the embodiments of the present invention includes the entire scope of the claims, and all available equivalents of the claims. In this article, relational terms such as first and second are used only to distinguish one entity or structure from another entity or structure, and do not require or imply any actual relationship between these entities or structures or order. The embodiments in this document are described in a progressive manner. Each embodiment focuses on the differences from other embodiments, and the same or similar parts between the embodiments can be referred to each other.

In the description of the present invention, it should be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", The azimuth or positional relationship indicated by "horizontal", "top", "bottom", "inner", "outer", etc. is based on the azimuth or positional relationship shown in the drawings, only for the convenience of describing the invention and simplifying the description, not Indicating or implying that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and therefore cannot be construed as limiting the present invention. In the description of the present invention, unless otherwise specified and limited, it should be noted that the terms “installation”, “connection”, and “connection” should be understood in a broad sense, for example, it may be mechanical or electrical, or two. The internal communication of each element may be directly connected or indirectly connected through an intermediate medium. For those of ordinary skill in the art, the specific meaning of the above terms can be understood according to specific circumstances.

In a general use environment, the air conditioner adjusts the temperature in the entire enclosed space, and it is difficult to accurately adjust the temperature of each part in the enclosed space. When adjusting the temperature in a room, the user is only in a certain part of the room, and the user can obtain a better user experience only by ensuring that the temperature of the part is appropriate. Using a mobile air conditioner, the temperature of each part of the enclosed space can be adjusted. In the present invention, the semiconductor temperature regulator 11 is used as the temperature adjustment component, so that excessive noise will not be generated during the temperature adjustment process, which brings better user experience.

According to a first aspect of the embodiments of the present invention, a portable air conditioner is provided.

As shown in FIG. 1, in an optional embodiment, the movable air conditioner includes:

Semiconductor temperature regulator 11, the first end of the semiconductor temperature regulator 11 is used to exchange heat with the environmental medium, wherein the first end is any one of the cold end 111 and the hot end 112 of the semiconductor temperature regulator 11; and,

The heat storage device 12 is in contact with the second end of the semiconductor temperature regulator 11 for exchanging heat with the second end of the cold end 111 and the hot end 112 of the semiconductor temperature regulator 11, wherein the second end is connected to the first end The other end of the cold end 111 and the hot end 112 of the semiconductor temperature regulator 11 corresponding to the end.

The temperature can be adjusted quietly, which is convenient for practical application and improves the user experience. In the cooling process, in this embodiment, the first end refers to the cold end 111 of the semiconductor temperature regulator 11, the second end refers to the hot end 112 of the semiconductor temperature regulator 11, and the cold end 111 of the semiconductor temperature regulator 11 Exchange heat with the environmental medium. The hot end 112 of the semiconductor temperature regulator 11 exchanges heat with the heat storage device 12 to introduce the heat in the environmental medium into the heat storage device 12 to achieve the cooling effect of the environmental medium. In the heating process, this The first end in the embodiment refers to the hot end 112 of the semiconductor temperature regulator 11, the second end refers to the cold end 111 of the semiconductor temperature regulator 11, the hot end 112 of the semiconductor temperature regulator exchanges heat with the ambient medium, The cold end 111 of the semiconductor temperature regulator 11 exchanges heat with the heat storage device 12 to introduce the heat of the heat storage device 12 into the environmental medium. At the same time, the heat generated by the semiconductor temperature regulator 11 during operation will also be dissipated into the environmental medium. To achieve the heating effect on environmental media. Moreover, the semiconductor temperature regulator 11 has no noise during operation, so the mobile air conditioner generates less noise during operation, is suitable for working in an indoor environment, and is convenient for practical application.

Environmental media refers to the substances in the individual components of the natural environment such as the atmosphere, water and soil.

As shown in FIG. 2, the semiconductor temperature regulator 11 includes: a cold end 111, a hot end 112, a metal conductor 113, and a semiconductor 114; the semiconductor 114 includes an N-type semiconductor and a P-type semiconductor. The N-type semiconductor passes through the metal conductor 113 and the P-type semiconductor In connection, the P-type semiconductor is connected to the N-type semiconductor through a metal conductor 113, and the plurality of metal conductors 113 are divided into two parts, one part is fixedly connected to the cold end 111, and the other part is fixedly connected to the hot end 112. Among them, the cold end 111 and the hot end 112 are insulating ceramic sheets. The positions of the cold end 111 and the hot end 112 of the semiconductor temperature regulator 11 are related to the direction of the current flowing through the semiconductor temperature regulator 11, and FIG. 2 shows an optional way of passing the semiconductor temperature regulator 11 The direction of the current flowing through the semiconductor temperature regulator 11 changes the position of the cold end 111 and the hot end 112 of the semiconductor temperature regulator.

In the above embodiment, the difference between the present mobile air conditioner is mainly pointed out. Obviously, as shown in FIG. 1, the mobile air conditioner further includes:

The housing 22 is provided with an air outlet and an air inlet. The air inlet and the air outlet are connected by an air duct, and the air duct passes through the cold end 111 or the hot end 112 of the semiconductor temperature regulator 11; and,

The mobile base 15 is provided at the lower part of the housing 22; and,

The power supply device 14 is electrically connected to the semiconductor temperature regulator 11 to provide electrical energy for the semiconductor temperature regulator 11; and,

The fan 23 is used to provide power for the flow of air on the surface of the semiconductor temperature regulator 11, and the fan 23 includes a cross-flow fan and an axial fan.

As shown in FIG. 3, the mobile air conditioner includes heat dissipation fins 115. The heat dissipation fins 115 are provided at the first end of the semiconductor temperature regulator 11 to increase the efficiency of the semiconductor temperature regulator 11 exchanging heat with the environmental medium. As shown in FIG. 3, the heat dissipation fin 115 is opposed to the fan 23.

As shown in FIG. 4, in an alternative embodiment, the movable base 15 includes:

The driving wheel 151 is provided at the lower part of the mobile base 15; and,

The driving motor 152 is disposed in the mobile base 15 and is drivingly connected to the driving wheel 151; and,

The guide wheel 153 is provided at the lower part of the moving base 15, and the guide wheel 153 and the drive wheel 151 are alternately arranged.

The technical solution can realize the movement of the base. Wherein, an optional driving motor 152 and driving wheel 151 are connected by a drive: the driving motor 152 and the driving wheel 151 are connected by a chain drive; an optional driving motor 152 is connected to the drive wheel 151 by an embodiment The drive motor 152 and the drive wheel 151 are connected by a belt drive; an optional implementation of the drive motor 152 and the drive wheel 151 is: the drive motor 152 and the drive wheel 151 are connected by a gear drive.

Optionally, the mobile base 15 includes two driving wheels 151, and correspondingly, the mobile base 15 includes two driving motors 152. That is, the rotation speed of each driving wheel 151 can be controlled independently. A universal wheel can be used as the driving wheel 151, and by controlling the rotation speeds of the two driving wheels 151, the air conditioner can go straight or turn.

Optionally, the mobile base 15 includes two drive wheels 151 and a drive motor 152. The mobile base 15 also includes a guide motor. The guide wheel 153 is rotatably connected to the mobile base 15 through a support shaft, and the guide motor is connected to the support shaft in a drive connection. In order to drive through the chain, it can be selected to be driven through a belt, optionally through a gear, and further, it can also be driven through a reducer. With the rotation of the guide motor, the support shaft can complete the rotation action, thereby driving the guide wheel 153 to complete the rotation action, so that the guide wheel 153 realizes the guide action.

Optionally, one or more passive wheels 154 are also provided, which are arranged at the lower part of the mobile base 15 and act with the movement of the mobile base 15. The load bearing capacity of the mobile base 15 can be increased. Optionally, the passive wheel 154 is a universal wheel, which reduces the resistance when the mobile base 15 turns.

Optionally, the diameter of the guide wheel 153 is larger than the diameter of the drive wheel 151, so that the friction force between the guide wheel 153 and the ground generates less torque, reducing the movement resistance of the moving base 15.

Taking the moving direction of the air conditioner as the front, optionally, the guide wheel 153 is in front of the drive wheel 151; alternatively, the drive wheel 151 is in front of the guide wheel 153.

Optionally, the mobile base includes an obstacle avoidance device 155, and the obstacle avoidance device 155 is disposed in front of the moving direction of the mobile base. The obstacle avoidance device 155 may be, but not limited to, an ultrasonic sensor or an infrared sensor.

As shown in FIGS. 12 and 13, optionally, a cleaning device 41 is provided at the bottom of the mobile base 15. The cleaning device 41 is used to clean the indoor floor and clean the dust deposited on the ground. After the dust on the ground is cleaned, when the mobile air conditioner moves indoors, the ground dust will not be excited into the indoor air, avoiding The dust on the ground causes secondary pollution to the indoor air, ensuring the cleanliness of the indoor air.

In an alternative embodiment, the mobile base 15 further includes a lifting mechanism 42, one end of the lifting mechanism 42 is fixed to the bottom of the mobile base 15, the other end of the lifting mechanism 42 is connected to the cleaning device 41, and the lifting mechanism 42 drags to clean The device 41 rises or falls. When the cleaning device 41 is lowered, the mobile air conditioner cleans the dust on the ground. When the cleaning device 41 is raised, the mobile air conditioner can move normally.

Optionally, the cleaning device 41 includes: a side brush 411, a roller brush 412, a dust box 413, a rag 414, and a water tank, and the side brush 411, a roller brush 412, a dust box 413, and a rag 414 are sequentially in front of the air conditioner It is provided that there are two or more side brushes 412, and the water tank is provided on the mobile base 15 and connected with the wiper 414 to provide moisture for the wiper 414. When the air conditioner is moving, the side brush 411 is used to collect the dust on both sides of the moving path to the center of the moving path, the roller brush 413 is used to collect the dust at the center of the moving path to the dust box 413, and the cloth 414 is used to clean the ground Further cleaning.

As shown in FIG. 14, optionally, the mobile air conditioner further includes:

The humidification device 51 is connected to the heat storage device 12 in the form of heat exchange. When the semiconductor temperature regulator 11 is used for cooling, the heat storage device 12 provides heat for the humidification device 51.

In the present technical solution, when the semiconductor temperature regulator 11 is used for cooling, the heat in the heat storage device 12 is utilized by the humidifying device 51 to humidify the indoor space and save energy. In addition, since the humidification device 51 consumes the heat in the heat storage device 12, the time that the air conditioner continues to operate can be extended.

Correspondingly, the detection device 21 includes a humidity sensor.

Optionally, the humidifying device 51 atomizes the water in the water storage unit 515 through the atomizer 511, and the atomized water enters the room through the air outlet 512. An air outlet valve 513 is provided at the air outlet 512.

Optionally, the water storage unit 515 of the humidifying device 51 communicates with the water tank through a duct 514. Optionally, a conduit valve 516 is provided where the conduit 514 communicates with the water storage unit 515.

When the air conditioner uses the rag 414 on the mobile base 15 to clean the ground, the water tank provides moisture to the rag 414. In this technical solution, the water storage unit 515 can supply water to the water tank through the duct 514, on the one hand, the rag 414 continues to clean On the other hand, it facilitates the process of adding water to the water tank.

Optionally, the mobile air conditioner further includes:

The heating chamber 52 is connected to the heat storage device 12 in the form of heat exchange. When the semiconductor temperature regulator 11 is used for cooling, the heat storage device 12 provides heat to the heating device 52.

When the semiconductor temperature regulator 11 is used for cooling, the heat in the heat storage device 12 is used by the heating device 52 to heat the object to be heated, for example, to heat the kettle, saving energy. In addition, the heat from the heat storage device 12 is consumed by the heating device 52, which can extend the continuous operation time of the air conditioner.

Optionally, a temperature sensor is included in the heating chamber 52.

Optionally, an electric heating device is provided in the heating chamber 52.

In an alternative embodiment, the heat storage device 12 is detachably provided on the air conditioner. It is convenient to replace the heat storage device 12.

Optionally, when the heat storage device 12 uses a fluid as a medium for storing heat, a fluid replacement valve is provided on the heat storage device 12 to cooperate with the fluid storage processing device (a device for reducing or increasing the temperature of the fluid, which can be moved with the original The device used with the air conditioner) replaces the fluid inside the heat storage device 12, that is, the fluid replacement valve is used to control the amount of fluid exchanged between the heat storage device 12 and the fluid storage processing device. After replacement, the portable air conditioner can work continuously.

For example, when the mobile air conditioner is used for cooling, the temperature in the heat storage device 12 is high, and the heat preservation device provided on the air conditioner can be used as the fluid storage processing device. At this time, the fluid storage processing device has a heating function; When the mobile air conditioner is used for heating, the temperature in the heat storage device is low, and the heat preservation device provided on the air conditioner is used as the fluid storage and processing device. At this time, the fluid storage and processing device has a cooling function.

In an alternative embodiment, the mobile air conditioner further includes a heat conduction device 13, the first part of the heat conduction device 13 is in contact with the second end of the semiconductor temperature regulator 11, for heat exchange with the second end, the heat conduction device The second part of 13 extends into the interior of the heat storage device 12 for heat exchange with the heat storage device 12.

Among them, the heat conduction device 13 is used to transfer heat between the second end of the semiconductor temperature regulator 11 and the heat storage device 12, when the semiconductor temperature regulator 11 is used for cooling, the second end is the hot end 112, the semiconductor temperature regulator The heat of the hot end 112 of the 11 can be transferred to the heat storage device 12 through the heat conduction device 13; when the semiconductor temperature regulator 11 is used for heating, the second end is the cold end 111, and the heat of the heat storage device 12 can pass through the heat conduction device 13 Transfer to the cold end 111 of the semiconductor temperature regulator 11.

In an alternative embodiment, the heat transfer medium of the heat transfer device 13 is metal.

Optionally, the heat conduction device 13 is any one of a cylindrical shape, a prismatic shape, and a mesa shape.

Optionally, the heat conduction device 13 is hollow or solid.

In an alternative embodiment, the heat-conducting device 13 is a pipeline containing a fluid, wherein the fluid is a heat-conducting medium.

Optionally, the heat-conducting device 13 further includes a water pump or an air pump for allowing fluid to sufficiently flow in the pipeline to sufficiently transfer heat between the second end of the semiconductor temperature regulator 11 and the heat storage device 12.

Optionally, when the heat-conducting medium in the heat-conducting device 13 is a fluid, the fluid is driven by the heat of the second end of the semiconductor temperature regulator 11 or the heat in the heat storage device 12 at the second end and the heat storage device 12 Cycle back and forth.

When the semiconductor temperature regulator 11 is used for cooling, the fluid absorbs heat at the second end, and then generates a driving force to flow to the heat storage device 12, the fluid after absorbing heat flows to the heat storage device 12, and the fluid is released at the heat storage device 12 The heat then generates a driving force to the second end, and the fluid after the heat release flows to the second end; when the semiconductor temperature regulator 11 is used for heating, the fluid releases heat at the second end to the heat storage device 12 The fluid flows to the second end after the heat storage device 12 absorbs the heat.

The fluid includes single-phase flow and multi-phase flow. The single-phase flow includes liquid and gas, and the multi-phase flow is a gas-liquid bidirectional flow.

Optionally, when the fluid is a single-phase flow, as shown in FIG. 5, the pipeline in the heat conduction device 13 is a closed circulation pipeline 131 connected end to end, including a first portion 1311 of the pipeline and a second portion of the pipeline The portion 1312 and the third portion 1313 of the pipeline, the first portion 1311 of the pipeline is in contact with the second end, the second portion 1312 of the pipeline extends into the interior of the heat storage device 12, and the third portion 1313 of the pipeline extends to the heat storage Inside the device 12, the first portion 1311 of the pipeline communicates with the second portion 1312 of the pipeline, the second portion 1312 of the pipeline communicates with the third portion 1313 of the pipeline, the third portion 1313 of the pipeline and the third portion of the pipeline A portion 1311 communicates; the second portion 1312 of the pipeline is higher than the first portion 1311 of the pipeline, and the first portion 1311 of the pipeline is higher than the third portion 1313 of the pipeline.

The technical solution is applicable to both the semiconductor temperature regulator 11 for cooling and the semiconductor temperature regulator 11 for heating, to ensure that the mobile air conditioner can not only cool and heat, but also play a role in temperature regulation. When the semiconductor temperature regulator 11 is used for cooling, the fluid circulation sequence is: the first part 1311 of the pipeline flows to the second part 1312 of the pipeline, then to the third part 1313 of the pipeline, and finally returns to the Part 1311; when the semiconductor temperature regulator 11 is used for heating, the circulation sequence of the fluid is: the first part 1311 of the pipeline flows to the third part 1313 of the pipeline, then flows to the second part 1312 of the pipeline, and finally returns The first part of the pipeline 1311.

When the fluid is a gas-liquid two-phase flow, in particular, it refers to a fluid undergoing phase change. As shown in FIG. 6, the circulation line 131 includes both gaseous fluid and liquid fluid, and the gaseous fluid and liquid fluid are the same substance, for example, the same refrigerant.

A fluid buffer bladder 1314 is provided between the second portion 1312 of the pipeline and the third portion 1313 of the pipeline, and the fluid buffer bladder 1314 can move up and down. For example, the fluid buffer bladder 1314 can be driven up and down by a hydraulic rod, a stepper motor, or a servo motor. The highest position of the fluid buffer bladder 1314 is higher than the height of the first portion 1311 of the pipeline; the lowest position of the fluid buffer bladder 1314 is lower than the height of the first portion 1311 of the pipeline. The volume of the fluid buffer bladder 1314 is greater than or equal to the volume of the first portion 1311 of the pipeline.

The ratio between the two-phase flow in the circulation line 131 needs to be ensured that: when the position of the fluid buffer bladder 1314 is higher than the first part 1311 of the pipeline, the first part 1311 of the pipeline is liquid fluid; when the fluid buffer bladder 1314 When the position is lower than the first portion 1311 of the pipeline, the gaseous fluid is in the first portion 1311 of the pipeline.

Control the height of the fluid buffer bag according to the cooling and heating status of the mobile air conditioner. When the mobile air conditioner is used for cooling, the position of the fluid buffer bag is controlled to be higher than that of the first part of the pipeline; when the mobile air conditioner is used During heating, the position of the control fluid buffer bladder is lower than the position of the first part of the pipeline.

Regardless of whether the mobile air conditioner is in the cooling or heating state, the semiconductor temperature regulator and the heat storage device can have better heat exchange efficiency.

In an alternative embodiment, a thermal insulation layer 124 is provided on the surface of the heat storage device 12. Therefore, the heat storage device 12 can better store heat, and the air conditioner has better cooling or heating effects. Optionally, the thermal insulation layer 124 is a resin material; alternatively, the thermal insulation layer 124 is polyurethane foam foam.

In an alternative embodiment, one or more layers of first semiconductor temperature regulators are provided between the second end of the semiconductor temperature regulator 11 and the heat-conducting device 13, wherein any one of the first semiconductor temperature regulators is cold End is in abutting connection with the hot end of another first semiconductor temperature regulator.

The temperature difference between the first end of the semiconductor temperature regulator and the heat storage device is increased, the capacity of the heat storage device to store heat is improved, and the mobile air conditioner continues to work longer.

Optionally, the shape of the first semiconductor temperature regulator matches the shape of the first portion of the heat conduction device, which can more specifically increase the temperature difference.

As shown in FIGS. 7 and 8, in an alternative embodiment, the movable air conditioner includes a first upper housing 223 and a first lower housing 224, a first upper housing 223 and a first lower Active matching of the housing 224;

The first upper casing 223 has an air outlet, the semiconductor temperature regulator 11 is disposed in the first upper casing 223 or the first lower casing 224, and the first end of the semiconductor temperature regulator 11 communicates with the air outlet through an air duct The heat storage device 12 is provided in the first upper casing 223 or the first lower casing 224.

The first upper casing 223 and the first lower casing 224 in this embodiment are the two parts of the casing 22 in the foregoing. Obviously, the first upper casing 223 is provided above the first lower casing 224, The first upper shell 223 is provided with an air outlet, that is, the mobile air conditioner blows outward through the first upper shell 223, and because the first upper shell 223 and the first lower shell 224 are movably matched, that is, the first upper shell The body 223 is movable relative to the first lower housing 224. The air outlet position of the air conditioner is adjustable, that is, the temperature adjustment position of the air conditioner is adjustable.

This embodiment includes the following optional application scenarios: In an optional application scenario, the semiconductor temperature regulator 11 is disposed in the first upper housing 223, and the heat storage device 12 is disposed in the first upper housing 223; In an optional application scenario, the semiconductor temperature regulator 11 is disposed in the first upper housing 223, and the heat storage device 12 is disposed in the first lower housing 224; in an optional application scenario, the semiconductor The temperature regulator 11 is disposed in the first lower housing 224, and the heat storage device 12 is disposed in the first upper housing 223; in an optional application scenario, the semiconductor temperature regulator 11 is disposed in the first lower portion In the housing 224, the heat storage device 12 is disposed in the first lower housing 224.

Optionally, the mobile base 15 is disposed at the lower portion of the first lower housing 224; optionally, the power supply device 14 is disposed within the first upper housing 223; alternatively, the power supply device 14 is disposed at the first lower housing Body 224.

Optionally, the manner in which the first upper shell 223 moves up and down is provided above the first lower shell 224. For example, the first upper housing 223 and the first lower housing 224 may be movably connected by a hydraulic rod. At this time, the air outlet of the air conditioner can be moved up and down, and the temperature of the air in the room can be adjusted at different heights. For example, when cooling, the height is increased, and the cold air is blown out at a higher position, and then falls under the action of gravity, making The temperature of the indoor air is more uniform; when heating, the height of the air outlet is reduced to make the temperature of the indoor air more uniform and the temperature adjustment effect is good.

The first upper shell 223 and the first lower shell 224 are movably matched, and can be optionally implemented as follows: the first upper shell 223 and the first lower shell 224 can be separated. Optionally, the first upper shell 223 and the first lower shell 224 can be matched with each other in the form of locking protrusions and locking slots, for example, the bottom of the first upper shell 223 is provided with locking protrusions, and the first lower shell 224 Corresponding card slots are provided on the upper part of the device; a card slot is provided on the bottom of the first upper case 223, and a corresponding card protrusion is provided on the upper part of the first lower case 224. When the first upper casing 223 and the first lower casing 224 are engaged with each other, the phenomenon of horizontal misalignment does not occur, and when the first upper casing 223 and the first lower casing 224 face each other in the vertical direction When moving, the first upper case 223 and the first lower case 224 are easily separated.

Optionally, there are one or more pairs of mutually matching locking protrusions and locking slots.

As shown in FIGS. 9 to 11, optionally, the mobile air conditioner further includes:

One or more rotors 17 are provided on the upper part of the first upper shell 223;

A first heat storage device 121 is also provided in the first upper housing 223, and the first heat storage device 121 is in contact with the second end of the semiconductor temperature regulator 11; a second heat storage device 122 is provided in the second lower housing 22;

The first heat storage device 121 and the second heat storage device 122 are two parts of the heat storage device 12, and the first heat storage device 121 and the second heat storage device 122 are in contact and can exchange heat with each other.

The rotor 17 can ensure that the first upper shell 223 moves upward relative to the first lower shell 224, so that the first upper shell 223 and the first lower shell 224 are separated from each other, and the rotor 17 can drag the first The upper case 223 moves to other positions. The first upper casing 223 is provided with a semiconductor temperature regulator 11 and a first heat storage device 121 to ensure that when the first upper casing 223 and the first lower casing 224 are separated from each other, the first upper casing 223 can still be independent Cooling or heating. By adopting this technical solution, the air conditioner can adjust the temperature in a larger range.

In the above optional technical solution, a first power supply device 141 is provided in the first upper housing 223, and the first power supply device 141 is electrically connected to the power end of one or more rotors 17 as the power end of one or more rotors 17 Power supply. The first power supply device 141 is electrically connected to the semiconductor temperature regulator 11 to supply power to the semiconductor temperature regulator 11. The first power supply device 141 is electrically connected to the fan 23 provided inside the first upper housing 223 to supply power to the fan 23; A second power supply device 142 is provided in the first lower housing 224. The second power supply device 142 is electrically connected to the movable base 15 to supply power to the movable base 15, when the first upper housing 223 and the first lower housing 224 When matching each other, the second power supply device 142 and the first power supply device 141 are electrically connected, and the second power supply device 142 supplies power to the first power supply device 141. Among them, the first power supply device 141 is a power storage device, the second power supply device 142 is a power storage device, or, the second power supply device 142 is a transformer device and a power cord, or the second power supply device 142 is a power storage device and a wireless The charging device, the wireless charging device is electrically connected to the power storage device, and the wireless charging device is provided at the bottom of the mobile base 15.

Optionally, the first power supply device 141 and the second power supply device 142 are electrically connected through a wireless charging device.

Optionally, the first power supply device 141 and the second power supply device 142 are detachably electrically connected through a copper pillar.

As mentioned above, the first upper housing 223 and the first lower housing 224 can be matched by means of the locking protrusion and the locking groove. Optionally, the number of locking protrusions 225 and the locking groove 226 is two or more pairs. The material of 225 and card slot 226 is copper or copper alloy. In the present technical solution, the locking protrusion 225 and the locking slot 226 not only have a fixing function, but also can connect the first power supply device 141 and the second power supply device 142.

Optionally, the number of the locking protrusions 225 and the locking grooves 226 is three pairs to ensure that each pair of locking grooves 226 and the locking protrusions 225 can be fully fitted, so that the first power supply device 141 and the second power supply device 142 are fully electrically connected. The number of the card protrusion 225 and the card slot 226 can also be four pairs, five pairs, six pairs and multiple pairs, which has a better supporting effect.

Alternatively, as shown in FIG. 11, the rotation axis of the rotor 17 is movably connected to the first upper housing 223 through the first steering mechanism 171, and the blade of the rotor 17 is movably connected to the rotation axis of the rotor 17 through the second steering mechanism 172, The first end of the semiconductor temperature regulator 11 is provided on the upper part of the first upper case 223. When the first upper housing 223 flies to the temperature-adjusting area, the blowing direction of the rotor 17 is adjusted by the first steering mechanism 171 and the second steering mechanism 172 to be blown toward the first end of the semiconductor temperature regulator 11. The rotor 17 has the functions of flying and accelerating the heat exchange effect of the first end of the semiconductor temperature regulator 11.

Optionally, the air conditioner includes a first upper shell 223 and two or more first lower shells 224; or, the air conditioner includes a first lower shell 224 and two or more first upper shells 223; or, the air conditioner includes two or more first upper housings 223 and two or more first lower housings 224.

When the heat in the second heat storage in the first lower housing 224 reaches the upper heat storage limit or the lower heat storage limit, the second heat storage device 122 needs to be replaced. If the air conditioner includes two or more first lower housings 224, when one of the first lower housings 224 needs to be replaced with the second heat storage device 122, the other first lower housings 224 can still continue to work, The first upper casing 223 is charged and the heat in the first heat storage device 121 is renewed through the second heat storage device 122 to improve the working efficiency of the air conditioner.

After the first upper casing 223 is separated from the first lower casing 224, when the first upper casing 223 is temperature-controlled alone, the first lower casing 224 is in an idle state at this time, if the air conditioner includes two or Multiple first upper casings 223, two or more first upper casings 223 can alternately charge the first power supply device 141 on the first lower casing 224, and update the The heat in the heat storage device 121 is high in the working efficiency of the air conditioner.

When the air conditioner includes two or more first upper housings 223 and two or more first lower housings 224, the two or more first upper housings 223 may take turns in the first lower housing 224 For charging and updating the heat in the first heat storage device 121, two or more first lower housings 224 can alternately replace the second storage device, which improves the working efficiency of the air conditioner.

In an alternative embodiment, the mobile air conditioner further includes a controller. Optionally, the controller is electrically connected to the driver of the driving motor 152; optionally, the controller is electrically connected to the driver of the steering motor; optionally, the controller is electrically connected to the driver of the semiconductor temperature regulator 11; optionally, The controller is electrically connected to the driver of the one or more rotors 17; optionally, the driver of the hydraulic rod between the first upper housing and the first lower housing 224 is electrically connected to the controller.

Optionally, when the mobile air conditioner performs the cleaning operation, the controller sends a control signal to other household electrical appliances to control the other household electrical appliances not to supply air to the air conditioning cleaning operation area.

In an optional embodiment, the movable air conditioner further includes a detection device 21, which is provided on the surface of the air conditioner's housing 22, is electrically connected to the controller, and sends a detection signal to the control. When the housing 22 of the air conditioner includes the first upper housing 223 and the first lower housing 224, the detection device 21 may be disposed on the surface of the first upper housing 223 or on the surface of the first lower housing 224.

The detection device 21 includes one or more of a temperature sensor, an infrared sensor, a human sensor, and an ultrasonic sensor.

Optionally, an alarm device is also included, which is electrically connected to the controller, wherein the alarm device includes one or more of an indicator light and a buzzer. The temperature sensor is provided inside the heat storage device 12 and sends the real-time temperature of the heat storage device 12 to the controller. When the temperature in the heat storage device 12 exceeds the upper limit temperature, it means that the heat in the heat storage device 12 reaches the upper limit of the heat storage, and the controller sends an alarm signal to the alarm device; when the temperature in the heat storage device 12 exceeds the lower limit temperature, that is Indicating that the heat in the heat storage device 12 has reached the lower limit of heat storage, the controller sends an alarm signal to the alarm device, and the alarm device emits light and / or beeps in response to the alarm signal.

In an optional embodiment, the mobile air conditioner further includes:

Air purification device for purifying respirable particles in indoor air; and,

Inhalable particle detection device for obtaining the concentration of inhalable particles in indoor air; and,

The communication device is used to send the concentration of respirable particles to the smart home system and receive control instruction information;

Control the operation of the air purification device according to the control instruction information.

Among them, the controller of the mobile air conditioner is used to control the operation of the air purification device according to the control instruction information.

In this technical solution, a mobile air conditioner can be added to a smart home system to cooperate with other air conditioning equipment to adjust the concentration of respirable particles in indoor air. The mobile air conditioner can establish a connection with the smart home system through the communication device, receive the control instruction information of the smart home system, and control the operation of the air purification device according to the control instruction information, so that it can jointly regulate the indoor air with other equipment in the smart home system Concentration of respirable particles.

In an optional embodiment, the mobile air conditioner further includes:

Temperature detection device for obtaining indoor ambient temperature; and,

The communication device is used to send the indoor environment temperature to the smart home system and receive the control instruction information sent by the smart home system;

Control the operation of the semiconductor temperature regulator according to the control instruction information.

Among them, the controller of the mobile air conditioner is used to control the operation of the semiconductor temperature adjusting device according to the control instruction information.

In this technical solution, a mobile air conditioner can be added to a smart home system to cooperate with other air conditioning equipment to adjust the indoor ambient temperature in the indoor air. The mobile air conditioner can establish a connection with the smart home system through the communication device, receive the control instruction information of the smart home system, and control the operation of the semiconductor temperature regulator according to the control instruction information, so as to jointly regulate the indoor air with other devices in the smart home system The ambient temperature in the room.

In an optional embodiment, the mobile air conditioner further includes:

Fresh air device for purifying carbon dioxide in indoor air; and,

Carbon dioxide detection device for obtaining the concentration of carbon dioxide in indoor air; and,

Communication device for sending carbon dioxide concentration to the smart home system and receiving control instruction information;

Control the operation of the fresh air device according to the control instruction information.

Among them, the controller of the mobile air conditioner is used to control the operation of the fresh air device according to the control instruction information.

In this technical solution, a mobile air conditioner can be added to a smart home system to cooperate with other air conditioning equipment to adjust the carbon dioxide concentration in indoor air. The mobile air conditioner can establish a connection with the smart home system through the communication device, receive the control instruction information of the smart home system, and control the operation of the fresh air device according to the control instruction information, so as to jointly adjust the indoor air with other equipment in the smart home system. Carbon dioxide concentration.

According to a second aspect of the embodiments of the present invention, a smart home system is provided.

In an optional embodiment, the smart home system includes the air conditioning cluster described above.

As shown in FIG. 15 and FIG. 16, in an optional embodiment, the smart home system includes the aforementioned mobile air conditioner, where the mobile air conditioner includes:

A semiconductor temperature regulator 11, the first end of the semiconductor temperature regulator 11 is used to exchange heat with the ambient medium, wherein the first end is any one of the cold and hot ends of the semiconductor temperature regulator 11; and,

The heat storage device 12 is in contact with the second end of the semiconductor temperature regulator 11 for exchanging heat with the second end of the cold and hot ends of the semiconductor temperature regulator 11, wherein the second end is in phase with the first end The other of the cold and hot ends of the corresponding semiconductor temperature regulator 11; and,

The heat replacement pipe 63, one end of the heat replacement pipe 63 communicates with the interior of the heat storage device 12, and the other end of the heat replacement pipe 63 is provided outside the air conditioner in a retractable manner;

The smart home system also includes:

The heat supply pipe 61 is provided in the indoor wall and / or the ground. The heat supply pipe 61 is used for heat release / heat absorption. The heat supply pipe 61 is provided with a heat exchange port 62, wherein the heat exchange port 62 is provided in the heat Replace the position where the other end of the pipeline 63 can contact.

By adopting the technical solution, it is convenient to add or release heat for the mobile air conditioner, so that the mobile air conditioner has better self-adaptability and can continuously adjust the indoor temperature. When the mobile air conditioner is working, the semiconductor temperature regulator needs to exchange heat with the heat storage device. When the heat in the heat storage device is too much or too little, the mobile air conditioner cannot work normally. In this technical solution, when the heat storage When there is too much or too little heat in the device, the heat can be released or absorbed through the heat replacement pipe. After the heat storage device exchanges heat with the heat supply pipe, the mobile air conditioner can work normally.

When the mobile air conditioner needs to exchange heat, the other end of the heat replacement line 63 extends through the heat exchange port 62 to communicate with the heat supply line 61. When the mobile air conditioner does not need to exchange heat, the heat replacement line 63 The other end extends and retracts without affecting the normal air conditioning process of the mobile air conditioner.

In an optional embodiment, a positioning mark that can be recognized by the mobile air conditioner is provided at the heat exchange port 62; correspondingly, a corresponding identification device is provided on the mobile air conditioner. For example, identification by infrared technology, identification by radio frequency identification technology, etc.

In an alternative embodiment, the heat supply line 63 includes: a first heat supply line, when the heat replacement line 63 communicates with the first heat supply line through the heat exchange port 62, the heat storage device 11 Heat is transferred to the first heat supply line; and, the second heat supply line, when the heat replacement line 61 communicates with the second heat supply line through the heat exchange port 62, the heat in the second heat supply line输 到 热 保护 装置 12。 Transmission to the heat storage device 12. With this technical solution, no matter the mobile air conditioner is in the cooling state or the heating state, it can exchange heat with the heat supply pipeline.

Optionally, when the heat storage device 12 and the heat supply line 61 exchange heat with a fluid as a medium, the heat replacement line 63 is provided with a fluid replacement valve.

In an alternative embodiment, the heat supply pipe 61 is provided in the wall, and the heat exchange port 62 is provided on the wall accessible by the heat replacement pipe 63 of the movable air conditioner; the heat replacement pipe 63 is provided On the side of the movable air-conditioning housing 22. It is convenient for the heat replacement pipeline 63 to be connected with the heat supply pipeline 61.

In an alternative embodiment, the heat supply line 61 is provided in the ground, and the heat exchange port 62 is provided on the ground accessible to the heat replacement line 63 of the mobile air conditioner; the heat replacement line 63 is provided in the The lower part of the mobile base of the mobile air conditioner. It is convenient for the heat replacement pipeline 63 to be connected with the heat supply pipeline 61.

In an alternative embodiment, a pipeline insulation layer is provided on the surface of the heat supply pipeline. Enhance the thermal insulation effect of the heat supply pipeline.

In an alternative embodiment, the heat replacement pipeline 63 includes a refrigerant input interface 641 and a refrigerant output interface 642; correspondingly, the heat supply pipeline is a refrigerant supply pipeline. By adopting the technical solution, the heat in the heat storage device 12 can be replaced.

As shown in FIGS. 17 and 18, in an alternative embodiment, the smart home system includes a mobile air conditioner, and the mobile air conditioner includes:

The first heat exchanger 64 is provided in the air conditioner casing, opposite to the air outlet of the air conditioner; and,

The refrigerant input interface 641 is provided on the housing of the air conditioner and communicates with the refrigerant input end of the first heat exchanger 64, and a first matching connector 643 is provided at the refrigerant input interface 641; and,

The refrigerant output interface 642 is provided on the housing of the air conditioner and communicates with the refrigerant output end of the first heat exchanger 64, and a first matching connector 643 is provided at the refrigerant output interface 642;

The smart home system also includes:

The refrigerant supply line 65 is used to supply refrigerant. The refrigerant supply line 65 is provided with a supply output interface 653 and a supply input interface 654. A second matching connector 655 is provided at the supply output interface 653, and a second match is provided at the supply input interface 654. The connecting piece 655 and the second matching connecting piece 655 are detachably connected with the first matching connecting piece 643.

The movable air conditioner does not need to drag the refrigerant pipeline all the time, which is convenient for movement. When the mobile air conditioner needs cooling or heating, it can be moved to the corresponding refrigerant supply line 65, and the refrigerant input line 651 and the refrigerant output line 652 are connected to the refrigerant supply line 65 through the first connection matching piece. The mobile air conditioner can adjust the air temperature. Therefore, the mobile air conditioner does not need to drag the pipeline during the moving process, which is convenient for movement.

In an alternative embodiment, the refrigerant supply line 65 includes a refrigerant input line 651 and a refrigerant output line 652, the supply output interface 653 is opened on the refrigerant output line 652, and the supply input interface 654 is opened on the refrigerant input tube On the road 651.

In an alternative embodiment, the number of supply output interfaces 653 is two or more, and correspondingly, the number of supply input interfaces 654 is two or more.

In an optional embodiment, a movable air conditioner recognizable positioning mark is provided around the supply output interface 653 and the supply input interface 654;

Correspondingly, corresponding identification devices are provided at corresponding positions of the refrigerant input interface 641 and the refrigerant output interface 642 of the mobile air conditioner.

For example, positioning using an identification device using infrared identification technology, or positioning using an identification device using short-range wireless communication technology.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning device includes one or more non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 19, the smart home system performs the following steps through its control center:

S1901: Obtain the adjustment function, adjustment efficiency, and operating power of each air-conditioning device.

Among them, the regulation function refers to the function that the air conditioning equipment has, for example, some air conditioning equipment has the function of adjusting temperature and purifying the air at the same time, and some air conditioning equipment has the function of fresh air and purifying the air at the same time.

The adjustment efficiency refers to the speed of adjusting an air index. For example, when adjusting the concentration of respirable particles, it is necessary to adjust the concentration of respirable particles from the first sample concentration to the second sample concentration in the space of the set volume Is the first time, and the first time is used to characterize the regulation efficiency.

The operating power refers to the power of the air-conditioning equipment when it runs the set adjustment function, including: the power when the air-conditioning equipment only runs the set adjustment function, and, when the air-conditioning equipment runs the set adjustment function and other adjustment functions at the same time Total power.

S1902: Determine a first group of air-conditioning devices having an air purification function among a plurality of air-conditioning devices.

The first group of air-conditioning equipment includes: air-conditioning equipment having only an air purification function, and air-conditioning equipment having both an air purification function and other adjustment functions.

S1903. Determine one or more combined operating parameters of the first group of air-conditioning adjustment devices according to the concentration of inhalable particles and the adjustment efficiency of each air-conditioning device;

Optionally, S1903 may be implemented as:

The first total regulation efficiency is determined according to the concentration of respirable particles. The first total regulation power refers to the total regulation efficiency of a plurality of air conditioning devices with air purification functions when regulating the concentration of respirable particles;

One or more air-conditioning devices that need to be operated are determined in the first group of air-conditioning devices based on the first total air-conditioning efficiency and the adjustment efficiency of each air-conditioning device, wherein the one or more first air-conditioning devices that need to be operated The sum of the adjustment efficiency of is greater than or equal to the first total adjustment efficiency.

By adopting the technical solution, multiple air-conditioning devices are controlled to adjust the inhalable particle concentration, which can ensure that the overall air-conditioning devices have a better adjustment efficiency and a good user experience.

Optionally, before S1903, it also includes:

Obtain the operating status of each air-conditioning device in the first group of air-conditioning devices;

S1903 can be implemented as:

The first total regulation efficiency is determined according to the concentration of respirable particles;

Determine the first remaining regulation efficiency according to the first total regulation efficiency and the operating state of each air conditioning device in the first group of air conditioning devices;

One or more air-conditioning devices that need to be operated are determined in the first group of air-conditioning devices based on the first remaining air-conditioning efficiency and the air-conditioning device's air-conditioning efficiency, wherein the one or more first air-conditioning devices that need to be operated The sum of the adjustment efficiency of is greater than or equal to the first remaining adjustment efficiency.

Fully taking into account the air conditioning equipment in operation, when adjusting the concentration of respirable particles, it can avoid the impact on other adjustment processes. For example, the stationary air conditioner A is adjusting the indoor temperature, and the stationary air conditioner A has the function of air purification. Keep the stationary air conditioner A to continue to operate. Subtract the fixed air conditioner A's inhalable particle concentration from the first total regulation efficiency Adjust the efficiency, and then use the first remaining adjustment efficiency to determine one or more air-conditioning equipment to be operated.

S1904. Determine, according to the operating power of each air-conditioning device, the first combined operating parameter with the smallest total power among the one or more combined operating parameters of the first group of air-conditioning devices;

S1905. Control the operation of the first group of air conditioning equipment according to the first combined operation parameter.

By adopting the technical solution, through the cooperation of the mobile air conditioner and other air purification equipment, the concentration of the respirable particles can be adjusted in an energy-saving manner.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning device includes one or more non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 20, the smart home system performs the following steps through its control center:

The smart home system performs the following steps through its control center:

S2001. Obtain the adjustment function, adjustment efficiency and operating power of each air-conditioning device.

S2002: Determine a second group of air-conditioning devices having a temperature-adjusting function among a plurality of air-conditioning devices.

The second group of air-conditioning equipment includes: air-conditioning equipment having only a function of adjusting temperature, and air-conditioning equipment having both a function of adjusting temperature and other functions of adjustment.

S2003. Determine one or more combined operating parameters of the second group of air conditioning equipment according to the indoor ambient temperature and the efficiency of each air conditioning equipment.

Alternatively, S2003 can be implemented as:

Determine the second total regulation efficiency according to the indoor ambient temperature;

One or more air-conditioning devices to be operated are determined in the second group of air-conditioning devices according to the second total air-conditioning efficiency and the adjustment efficiency of each air-conditioning device, wherein the one or more second air-conditioning devices to be operated The sum of the adjustment efficiency of is greater than or equal to the second total adjustment efficiency.

Adopting the technical solution to control multiple air-conditioning devices to adjust the indoor ambient temperature can ensure that the multiple air-conditioning devices as a whole have better adjustment efficiency and a good user experience effect.

Optionally, before S2003, it also includes:

Obtain the operating status of each air-conditioning device in the second group of air-conditioning devices;

S2003 can be implemented as:

Determine the second total regulation efficiency according to the indoor ambient temperature;

Determine the second remaining regulation efficiency according to the second total regulation efficiency and the operating state of each air conditioning device in the second group of air conditioning devices;

The one or more air-conditioning devices that need to be operated are determined in the second group of air-conditioning devices according to the second remaining adjustment efficiency and the adjustment efficiency of each air-conditioning device, wherein the one or more second air-conditioning devices that need to be operated The sum of the adjustment efficiency of is greater than or equal to the second remaining adjustment efficiency.

Fully considering the running air conditioning equipment, when adjusting the indoor ambient temperature, it can avoid the impact on other adjustment processes. For example, the fixed air conditioner B is performing the fresh air function, and the fixed air conditioner B has the function of adjusting the temperature, keeping the fixed air conditioner B to continue to operate, subtracting the adjustment of the fixed air conditioner B to the indoor ambient temperature from the second total adjustment efficiency Efficiency, and then use the second residual conditioning efficiency to determine one or more air conditioning equipment that needs to be operated.

S2004. Determine the second combined operating parameter with the smallest total power among the combined operating parameters of the one or more second groups of air conditioning devices according to the operating power of each air conditioning device;

S2005. Control the operation of the second group of air conditioning equipment according to the second combined operation parameter.

Using this technical solution, through the cooperation of the mobile air conditioner and other temperature adjustment equipment, the indoor temperature can be adjusted in an energy-saving manner.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning device includes one or more non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 21, the smart home system performs the following steps through its control center:

S2101: Obtain the adjustment function, adjustment efficiency, and operating power of each air-conditioning device.

S2102. Determine a third group of air-conditioning devices with fresh air function among the multiple air-conditioning devices.

The third group of air conditioning equipment includes: air conditioning equipment with fresh air function only, and air conditioning equipment with fresh air function and other air conditioning equipment with other air conditioning functions.

S2103. Determine one or more combined operating parameters of the third group of air conditioning and conditioning equipment according to the carbon dioxide concentration and the efficiency of each air conditioning equipment;

Alternatively, S2103 may be implemented as:

The third total regulation efficiency is determined according to the carbon dioxide concentration, and the third total regulation power refers to the total regulation efficiency of multiple air conditioning equipment with fresh air function when regulating the carbon dioxide concentration;

According to the third total air-conditioning efficiency and the air-conditioning equipment's air-conditioning equipment efficiency, one or more air-conditioning equipment to be operated are determined in the third group of air-conditioning equipment, wherein the one or more third air-conditioning equipment to be operated The sum of the adjustment efficiency of is greater than or equal to the third total adjustment efficiency.

Adopting the technical solution to control multiple air-conditioning equipment to adjust the carbon dioxide concentration can ensure that the multiple air-conditioning equipment as a whole have better adjustment efficiency and a good user experience effect.

Optionally, before S2103, it also includes:

Obtain the operating status of each air-conditioning device in the third group of air-conditioning devices;

S2103 can be implemented as:

Determine the third total regulation efficiency according to the carbon dioxide concentration;

Determine the third remaining regulation efficiency according to the third total regulation efficiency and the operating state of each air conditioning device in the third group of air conditioning devices;

One or more air-conditioning devices that need to be operated are determined in the third group of air-conditioning devices according to the third remaining adjustment efficiency and the adjustment efficiency of each air-conditioning device. The sum of the adjustment efficiency of is greater than or equal to the third remaining adjustment efficiency.

Fully taking into account the air conditioning equipment in operation, when adjusting the carbon dioxide concentration, it can avoid the impact on other adjustment processes. For example, the stationary air conditioner C is adjusting the indoor temperature, and the stationary air conditioner C has the function of fresh air, to keep the stationary air conditioner C to continue to operate, subtracting the regulation efficiency of the stationary air conditioner C on the carbon dioxide concentration from the third total regulation efficiency, The third remaining adjustment efficiency is then used to determine one or more air-conditioning equipment to be operated.

S2104: Determine, according to the operating power of each air-conditioning device, the third combined operating parameter with the smallest total power among the combined operating parameters of one or more third groups of air-conditioning devices;

S2105. Control the operation of the third group of air conditioning equipment according to the third combined operation parameter.

Using this technical solution, through the cooperation of the mobile air conditioner and other fresh air equipment, the carbon dioxide concentration can be adjusted in an energy-saving manner.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning device includes one or more non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 22, the smart home system performs the following steps through its control center:

S2201: Obtain the adjustment function, adjustment efficiency, and operating power of each air-conditioning device.

S2202: Determine a fourth group of air-conditioning devices having a function of adjusting humidity among a plurality of air-conditioning devices.

The fourth group of air-conditioning equipment includes: air-conditioning equipment having only the function of adjusting humidity, and air-conditioning equipment having both the function of adjusting humidity and other functions of adjustment.

S2203. Determine one or more combined operating parameters of the fourth group of air conditioning and conditioning equipment according to the indoor environmental humidity and the efficiency of each air conditioning equipment;

Alternatively, S2203 may be implemented as:

The fourth total regulation efficiency is determined according to the indoor environmental humidity, and the fourth total regulation power refers to the total regulation efficiency of a plurality of air-conditioning equipment with air purification functions when regulating the indoor environmental humidity;

According to the fourth total air-conditioning efficiency and the air-conditioning equipment's air-conditioning equipment efficiency, one or more air-conditioning equipment that needs to be operated are determined in the fourth group of air-conditioning equipment, wherein the one or more fourth air-conditioning equipment that needs to be operated The sum of the adjustment efficiencies is greater than or equal to the fourth total adjustment efficiency.

Adopting the technical solution to control a plurality of air-conditioning equipment to adjust the indoor environment humidity can ensure that the plurality of air-conditioning equipment as a whole have better adjustment efficiency and a good user experience effect.

Optionally, before S2203, it also includes:

Obtain the operating status of each air-conditioning device in the fourth group of air-conditioning devices;

S2203 can be implemented as:

Determine the fourth total regulation efficiency according to the indoor environmental humidity;

Determine the fourth remaining regulation efficiency according to the fourth total regulation efficiency and the operating state of each air conditioning device in the fourth group of air conditioning devices;

One or more air-conditioning devices that need to be operated are determined in the fourth group of air-conditioning devices according to the fourth remaining adjustment efficiency and the adjustment efficiency of each air-conditioning device, wherein the one or more fourth air-conditioning devices that need to be operated The sum of the adjustment efficiency of is greater than or equal to the fourth remaining adjustment efficiency.

Fully considering the running air conditioning equipment, when adjusting the indoor environmental humidity, it can avoid the impact on other adjustment processes. For example, the fixed air conditioner D is adjusting the indoor temperature, and the fixed air conditioner D has the function of adjusting the humidity. Keep the fixed air conditioner D to continue to operate, subtracting the adjustment of the indoor air humidity of the fixed air conditioner D from the fourth total adjustment efficiency Efficiency, and then use the fourth residual conditioning efficiency to determine one or more air conditioning equipment to be operated.

S2204. Determine a fourth combined operating parameter with the smallest total power among the combined operating parameters of one or more fourth groups of air conditioning devices according to the operating power of each air conditioning device;

S2205. Control the operation of the fourth group of air conditioning equipment according to the fourth combined operation parameter.

Using this technical solution, through the cooperation of a mobile air conditioner and other air purification equipment, the indoor environment humidity can be adjusted in an energy-saving manner.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning devices include non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 23, the smart home system performs the following steps through its control center:

S2301: Determine, according to the first actual air index to be adjusted, a fifth group of air conditioning devices having a function of adjusting the first actual air index among two or more air conditioning devices.

Each air-conditioning equipment has one or more adjustment functions, for example, some air-conditioning equipment only has the function of adjusting temperature, some air-conditioning equipment has the function of adjusting temperature and humidity, and some air-conditioning equipment has the function of adjusting The function of temperature, the function of adjusting humidity, the function of purifying air.

The fifth group of air conditioning equipment includes air conditioning equipment having only the function of adjusting the first actual air index, and / or air conditioning equipment having both the function of adjusting the first actual air index and the function of adjusting other air indexes .

S2302. Determine a fifth combined operating parameter that meets the set regulation efficiency according to the regulation efficiency of each air-conditioning device.

The set regulation efficiency includes the total regulation efficiency of all the air conditioning devices in the fifth group of air conditioning devices, or the average regulation efficiency of each air conditioning device of the fifth group of air conditioning devices. The set adjustment efficiency may be set by the user, may be factory default settings, or may be determined according to the adjustment efficiency of each air-conditioning device in the fifth group of air-conditioning devices.

Optionally, S2302 determines a fifth combined operating parameter that meets the set regulation efficiency according to the regulation efficiency of each air-conditioning device, which may be implemented as:

One or more combined operating parameters of the fifth group of air conditioning devices are determined according to the first actual air index and the adjusting efficiency of each air conditioning device, where the combined operating parameters of the fifth group of air conditioning devices include the fifth group of air In the air conditioning equipment, the start / stop status of each air conditioning equipment, the operating power of the air conditioning equipment that has been started;

A fifth combined operating parameter consistent with the set regulation efficiency is determined among the combined operating parameters of one or more fifth groups of air conditioning equipment. Among them, according to the combined operating parameters of the fifth group of air conditioning equipment and the adjustment efficiency of each air conditioning equipment, it can be determined that under each combined operating parameter, the total or average adjusted power of the fifth group of air conditioning equipment can be Among the various operating parameters, the combined operating parameters that meet the set regulation power are determined.

Optionally, the adjustment efficiency is set to one of the combined operation parameters of the fifth group of air conditioning equipment, the total adjustment efficiency being the highest. It can better improve the regulation power of the fifth group of air conditioning equipment.

Optionally, determining a fifth combined operating parameter that meets the set regulation efficiency according to the regulation efficiency of each air conditioning device, including: determining one or more based on the first actual air index and the regulation efficiency of each air conditioning device The combined operating parameters of the fifth group of air conditioning equipment; the total operating power of the combined operating parameters of each fifth group of air conditioning equipment is obtained according to the operating power of the air conditioning equipment; the efficiency and total operating power of each air conditioning equipment A fifth combined operating parameter consistent with the set regulation efficiency is determined among the combined operating parameters of one or more fifth groups of air conditioning equipment.

In this technical solution, considering the total operating power of the fifth group of air-conditioning equipment and the adjustment efficiency of each air-conditioning equipment, when the adjustment efficiency of the fifth group of air-conditioning equipment is improved, the fifth group of air-conditioning can also be reduced The operating power of the device.

Optionally, according to the adjustment efficiency and the total operating power of each air-conditioning device, a fifth combination operation parameter that meets the set adjustment efficiency is determined from one or more combined operation parameters of the fifth group of air-conditioning devices, which can be implemented for:

According to the total adjustment power or average adjustment power of the fifth group of air conditioning equipment, and, the total operating power determines the comprehensive reference value;

When the comprehensive reference value is minimum, it is determined that the total or average adjusted power of the fifth group of air-conditioning equipment at this time meets the set adjusted power, and the combined operating parameter is used as the fifth combined operating parameter.

Among them, the comprehensive reference value can be obtained by the following formula:

Z = a * X + b * Y, where Z is the comprehensive reference value, X is the total operating power, Y is the regulation efficiency, and a and b are the coefficients.

At the same time, the air index is adjusted in an energy-saving and efficient manner.

S2303. Control the operation of the fifth group of air conditioning equipment according to the fifth combined operation parameter.

In this technical solution, the adjustment efficiency of adjusting the first actual air index is improved. When the first actual air index needs to be adjusted, first select the air conditioning equipment with the function of adjusting the set air index, and then select the appropriate air based on the adjustment efficiency of each air conditioning equipment to the set air index The adjustment device adjusts the set air index, which improves the adjustment efficiency of adjusting the set air index.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning devices include non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 24, the smart home system performs the following steps through its control center:

S2401: Obtain weather information.

Optionally, the weather information includes one or more of temperature information, humidity information, and respirable particle concentration information.

S2402: Determine the operating parameters of each air-conditioning device according to the weather information.

Optionally, the operating parameters of the air conditioning equipment include any one or more of a start / stop state, an adjustment function, an operating power, and an adjustment efficiency. Among them, the adjustment function is the function that the air-conditioning equipment is performing, for example, the air-conditioning equipment adjusts the indoor temperature, at this time the adjustment function is the temperature adjustment function; The equipment adjusts the concentration of inhalable particles in the room, and the adjustment function is to adjust the concentration of inhalable particles.

Optionally, S2402 determines the operating parameters of each air-conditioning device according to the weather information, including:

The comfort air index is determined according to the weather information, and the operating parameters of each air conditioning device are determined according to the comfort air index. Among them, the comfort air index corresponds to the weather information, and under the comfort air index, the user obtains a better user experience.

Weather information will not only affect the operating parameters of the air conditioning equipment in the smart home system, but also affect other devices in the smart home system, such as water heaters. When users take a bath, the temperature of the water heater they need is related to the ambient temperature. Generally Under the circumstances, the lower the outdoor ambient temperature, the lower the indoor ambient temperature. At this time, the water heater needs to maintain a higher temperature, which can provide users with a better bathing experience. Therefore, when the outdoor ambient temperature decreases, the temperature of the water heater is increased.

S2403: Control the operation of the corresponding air conditioning equipment according to the operating parameters of each air conditioning equipment.

In this smart home system, the operating parameters of each air-conditioning device are adjusted according to the weather information, which can automatically adapt to the weather information and provide users with a better experience.

In an optional embodiment, the smart home system includes two or more air-conditioning devices, the air-conditioning devices include non-removable air-conditioning devices, and, the aforementioned movable air conditioner;

As shown in Figure 25, the smart home system performs the following steps through its control center:

S2501: Obtain the average operating parameters of two or more other air-conditioning equipment in the set area.

Optionally, the setting area is the cell where the user is located. In the same cell, the similarity of weather information is higher, and more accurate average operating parameters can be obtained.

Optionally, S2501 obtains the average operating parameters of two or more other air-conditioning equipment in the set area, which may be implemented as: obtaining two or more real-time operations of two or more other air-conditioning equipment in the set area Parameters, based on two or more real-time operating parameters to obtain the average operating parameters. With this technical solution, the user still has a better user experience in special weather, such as a sudden drop or rise in the outdoor ambient temperature.

Optionally, S2501 obtains the average operating parameters of two or more other air-conditioning equipment in the set area, which may be implemented as: obtaining two or more historical operations of two or more other air-conditioning equipment in the set area Parameters, based on two or more historical operating parameters to obtain the average operating parameters. With this technical solution, the obtained average operating parameters have good stability and are not easily affected by accidental factors, such as strong convective weather lasting more than ten minutes.

Optionally, the historical operating parameters are the operating parameters at the same time point in the historical date. For example, to obtain the historical operating parameters at the first moment of today (such as 9:00 am), you need to obtain the operating parameters at the first moment of yesterday and the day before yesterday The operating parameters at the first moment, and so on.

S2502. Control the operation of the air conditioning equipment according to the average operating parameters.

In this technical solution, the smart home system can acquire the operating parameters of the air conditioning equipment of other users, and use the average operating parameters of the air conditioning equipment of other users as the operating parameters of the air conditioning equipment in the smart home system. The average operating parameters of the air conditioning equipment of other users reflect the operating parameters required by the air conditioning equipment when other users have a better user experience. In the same area, the weather information is similar, so using the average operating parameters of other users' air conditioning equipment as the operating parameters of the air conditioning equipment in the smart home system, the user can still get a better experience and avoid The user manually sets the operating parameters of the smart home system.

It should be understood that the present invention is not limited to the processes and structures already described above and shown in the drawings, and various modifications and changes can be made without departing from the scope thereof. The scope of the invention is only limited by the appended claims.

Claims (10)

1. A smart home system includes two or more air-conditioning equipment, characterized in that the air-conditioning equipment includes non-removable air-conditioning equipment and a mobile air conditioner;

   The movable air conditioner includes:

   A semiconductor temperature regulator, the first end of the semiconductor temperature regulator is used to exchange heat with an environmental medium, wherein the first end is any one of the cold and hot ends of the semiconductor temperature regulator; and,

   A heat storage device, which is in contact with the second end of the semiconductor temperature regulator and used to exchange heat with the second end of the cold and hot ends of the semiconductor temperature regulator, wherein the second end is The other end of the cold end and the hot end of the semiconductor temperature regulator corresponding to the first end;

   The smart home system performs the following steps through its control center:

   Get weather information;

   Determine the operating parameters of each air-conditioning device according to the weather information;

   Control the operation of the corresponding air conditioning equipment according to the operating parameters of each air conditioning equipment.
2. The smart home system of claim 1, wherein the weather information includes one or more of temperature information, humidity information, and inhalable particle concentration information.
3. The smart home system according to claim 1, wherein the operating parameters of the air-conditioning device include any one or more of a start / stop state, an adjustment function, an operation power, and an adjustment efficiency.
4. The smart home system according to claim 1, wherein the determining the operating parameters of each air-conditioning device according to the weather information includes:

   Determine the comfortable air index according to the weather information;

   The operating parameters of each air-conditioning device are determined according to the comfort air index.
5. The smart home system according to claim 1, wherein the movable air conditioner further comprises:

   The humidification device is connected to the heat storage device in the form of heat exchange. When the semiconductor temperature regulator is used for cooling, the heat storage device provides heat to the humidification device.
6. The smart home system according to claim 1, wherein the movable air conditioner further comprises:

   A mobile base, the lower part of the mobile base is provided with a rag for cleaning the ground, a water tank connected to the rag is provided on the base, and the water tank is used for supplying water to the rag;

   The water storage unit of the humidification device communicates with the water tank through a conduit.
7. The smart home system according to claim 1, wherein the movable air conditioner further comprises:

   The heating chamber is connected to the heat storage device in the form of heat exchange, and when the semiconductor temperature regulator is used for cooling, the heat storage device provides heat to the heating device.
8. The smart home system according to claim 1, wherein the movable air conditioner further comprises:

   Air purification device for purifying respirable particles in indoor air.
9. The smart home system according to claim 1, wherein the movable air conditioner further comprises:

   Fresh air device for purifying carbon dioxide in indoor air.
10. The air conditioner according to claim 1, wherein the movable air conditioner further comprises:

    A heat conduction device, a first portion of the heat conduction device is in contact with the second end of the semiconductor temperature regulator for heat exchange with the second end, and a second portion of the heat conduction device extends to the heat The interior of the storage device is used for heat exchange with the heat storage device;

    When the heat conduction medium in the heat conduction device is a fluid, the fluid is driven by the heat of the second end of the semiconductor temperature regulator or the heat in the heat storage device, at the second end and the The heat storage device circulates back and forth.

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