CN110811004A - Air conditioning clothes and control method thereof - Google Patents

Abstract

The invention discloses an air conditioning coat and a control method thereof, and belongs to the field of refrigeration equipment. The air-conditioning clothes comprise wearable equipment and a temperature control system; the control method comprises the following steps: acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition; determining whether a regulation condition is satisfied based on the external ambient temperature and the internal humidity; the regulation and control conditions comprise that the external environment temperature is in a temperature interval for representing that a user feels extremely hot, and the internal humidity is in a humidity interval for representing that the user feels moderate; responding to the external environment temperature and the internal humidity to determine that the regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the regulation condition; the regulation and control rule comprises the steps of controlling the solution humidity control device to operate in a dehumidification mode, controlling the compressor and the circulating water pump to operate according to set parameters, and controlling the first outer fan to operate in a high wind gear and the second outer fan to operate in a high wind gear. The control method provided by the invention realizes intelligent, efficient and energy-saving operation of the air conditioning clothes.

Description

Air conditioning clothes and control method thereof

Technical Field

The invention relates to the field of refrigeration equipment, in particular to an air conditioning clothes and a control method thereof.

Background

In some special working occasions, such as high-altitude erection of a national power grid high-voltage line, army military battle, duty traffic police, army exercise, field investigation and the like, the working environment is severe, personnel often need to be tested by adverse environmental factors such as high-temperature hot or low-temperature freezing, and the like, and the physical health of the personnel is easily influenced if the personnel are in the severe working environment for a long time. Aiming at the special working occasions, products such as air conditioning clothes and the like are designed in the prior art to improve the working environment of personnel, and the air conditioning clothes are also called as heat (cold) proof clothes.

The existing air conditioning clothes mainly comprise a clothes body, a refrigeration module and a power supply module; the clothes body is filled with fluid which can perform circulating heat exchange with a refrigeration mode, and the power supply module can provide power for the refrigeration module, so that the refrigeration module can refrigerate or heat the fluid, and the stability of the close-fitting temperature of a user is ensured in a hot or cold working environment.

However, the existing air-conditioning clothes are started to operate according to fixed power or manually adjusted among a limited number of gears by a user, so that the actual working state of the air-conditioning clothes is often not matched with the current working environment and the body state of the user, the optimal cooling/heating effect cannot be achieved, and extra power consumption is wasted.

Disclosure of Invention

The invention provides an air conditioning clothes and a control method thereof, aiming at solving the defect that the working state of the existing air conditioning clothes can not be adjusted or can only be adjusted manually by a user. The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview and is intended to neither identify key/critical elements nor delineate the scope of such embodiments. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

According to a first aspect of the invention, a control method of an air-conditioning coat is provided, the air-conditioning coat comprises a wearable device and a temperature control system, wherein a pipeline for supplying water to flow and exchanging heat with a human body is arranged in the wearable device, and a circulating water pump for circulating the water in the pipeline is arranged on the pipeline; the temperature control system is used for reducing or increasing the temperature of water in the pipeline, the temperature control system comprises an air conditioning module connected with the pipeline, the air conditioning module comprises a compressor, a first heat exchanger used for exchanging heat with the external environment, a throttling element and a second heat exchanger used for exchanging heat with the inside of the air conditioning clothes, and a first outer fan and a second outer fan used for radiating heat for the first heat exchanger are arranged at the first heat exchanger; the air-conditioning clothes also comprise a temperature sensor for detecting the temperature of the external environment and a humidity sensor for detecting the internal humidity; the air conditioning clothes also comprise a solution humidifying device for adjusting the humidity inside the air conditioning clothes;

the air-conditioning coat is preset with at least six interval threshold values which are sequentially increased and used for corresponding temperature interval rules representing user feelings at least comprising cold, low cold, moderate, high heat, hot and extremely hot; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the control method comprises the following steps:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels extremely hot, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the circulating water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a high wind gear.

In an optional embodiment, the control method further comprises:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In an optional embodiment, the air-conditioning clothes further comprise a power supply, wherein the power supply comprises a solar power generation panel and a lithium battery, and the solar power generation panel is connected with the lithium battery through a first output line and is used for charging the lithium battery; the solar power generation panel is connected with the air conditioning module through a second output line and used for supplying power to the air conditioning module; a first switch is arranged on a circuit for connecting the lithium battery and the solar power generation panel, a second switch is arranged on a circuit for connecting the lithium battery and the air conditioning module, and a third switch is arranged on a circuit for connecting the solar power generation panel and the air conditioning module; the first switch, the second switch and the third switch are respectively used for controlling the on-off of the circuit;

control switches over from air conditioner clothing battery power supply mode to standby power supply mode, includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In an alternative embodiment, the setting parameter of the compressor comprises a setting frequency, and the setting frequency is calculated according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.7.

In an alternative embodiment, the setting parameter of the circulating water pump comprises a set flow rate, and the set flow rate is a maximum flow rate value of the circulating water pump.

According to a second aspect of the invention, an air-conditioning coat is provided, which comprises a wearable device and a temperature control system, wherein a pipeline for supplying water to flow and exchanging heat with a human body is arranged in the wearable device, and a circulating water pump for circulating the water in the pipeline is arranged on the pipeline; the temperature control system is used for reducing or increasing the temperature of water in the pipeline, the temperature control system comprises an air conditioning module connected with the pipeline, the air conditioning module comprises a compressor, a first heat exchanger used for exchanging heat with the external environment, a throttling element and a second heat exchanger used for exchanging heat with the inside of the air conditioning clothes, and a first outer fan and a second outer fan used for radiating heat for the first heat exchanger are arranged at the first heat exchanger; the air-conditioning clothes also comprise a temperature sensor for detecting the temperature of the external environment and a humidity sensor for detecting the internal humidity; the air conditioning clothes also comprise a solution humidifying device for adjusting the humidity inside the air conditioning clothes;

the air-conditioning suit also comprises a controller, wherein the controller is preset with temperature interval rules which are sequentially increased by at least six interval thresholds and used for corresponding representations of user feelings including at least cold, low cold, moderate, high heat, hot and extremely hot; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels extremely hot, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the circulating water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a high wind gear.

In an alternative embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In an optional embodiment, the air-conditioning clothes further comprise a power supply, wherein the power supply comprises a solar power generation panel and a lithium battery, and the solar power generation panel is connected with the lithium battery through a first output line and is used for charging the lithium battery; the solar power generation panel is connected with the air conditioning module through a second output line and used for supplying power to the air conditioning module; a first switch is arranged on a circuit for connecting the lithium battery and the solar power generation panel, a second switch is arranged on a circuit for connecting the lithium battery and the air conditioning module, and a third switch is arranged on a circuit for connecting the solar power generation panel and the air conditioning module; the first switch, the second switch and the third switch are respectively used for controlling the on-off of the circuit;

the controller is specifically configured to: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In an alternative embodiment, the set parameter of the compressor comprises a set frequency, and the controller calculates the set frequency according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.7.

In an alternative embodiment, the setting parameter of the circulating water pump comprises a set flow rate, and the set flow rate is a maximum flow rate value of the circulating water pump.

The invention adopts the technical scheme and has the beneficial effects that:

according to the control method of the air conditioning clothes, the operation of relevant parts of the air conditioning clothes can be controlled to be automatically adjusted according to corresponding regulation rules when the regulation conditions of extremely hot temperature and dry humidity are met according to the detected external environment temperature and internal humidity of the air conditioning clothes under the refrigeration working condition, so that the air conditioning clothes can reach the working state matched with the current temperature and humidity, the control accuracy of the air conditioning clothes is greatly improved, and the intelligent, efficient and energy-saving operation of the air conditioning clothes is realized.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

FIG. 1 is a first schematic view of an air conditioning garment of the present invention according to an exemplary embodiment;

FIG. 2 is a schematic structural diagram of an air conditioning garment of the present invention shown in accordance with an exemplary embodiment;

FIG. 3 is a schematic structural diagram of a wearable device shown in accordance with an exemplary embodiment;

FIG. 4 is a schematic flow chart illustrating a method of controlling an air conditioning garment of the present invention according to an exemplary embodiment;

FIG. 5 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

FIG. 6 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

FIG. 7 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

FIG. 8 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

FIG. 9 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

fig. 10 is a flowchart illustrating a control method of an air-conditioning suit according to still another exemplary embodiment of the present invention.

Wherein, 1-wearable equipment, 2-temperature control system; 11-pipeline, 12-first solution membrane, 13-second solution membrane, 14-water pipe, 15-booster water pump, 16-heat transfer layer, 17-adsorption layer and 18-heat insulation layer; 21-air conditioning module, 22-power supply; 111-a water inlet, 112-a water outlet, 113-a first connecting pipe, 114-a second connecting pipe, 115-a circulating water pump, 116-a water tank, 117-a pressure relief valve; 171-first output line, 172-second output line, 173-first switch, 174-second switch, 175-third switch; 211-compressor, 212-first heat exchanger, 213-throttling element, 214-second heat exchanger, 215-reversing valve; 1161-a water replenishing valve; 2111-exhaust port, 2112-intake port; 2121-a first external fan; 2122-a second external fan; 2141-a first air tube connector, 2142-a second air tube connector, 2143-a first water tube connector, 2144-a second water tube connector; 2151-first interface, 2152-second interface, 2153-third interface, 2154-fourth interface.

Detailed Description

The following description and the drawings sufficiently illustrate specific embodiments of the invention to enable those skilled in the art to practice them. Other embodiments may incorporate structural, logical, electrical, process, and other changes. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The scope of embodiments of the invention encompasses the full ambit of the claims, as well as all available equivalents of the claims. Embodiments may be referred to herein, individually or collectively, by the term "invention" merely for convenience and without intending to voluntarily limit the scope of this application to any single invention or inventive concept if more than one is in fact disclosed. Herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method or apparatus that comprises the element. The embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. As for the methods, products and the like disclosed by the embodiments, the description is simple because the methods correspond to the method parts disclosed by the embodiments, and the related parts can be referred to the method parts for description.

FIG. 1 is a first schematic view of an air conditioning garment of the present invention according to an exemplary embodiment; fig. 2 is a schematic structural diagram ii of the air-conditioning garment of the present invention according to an exemplary embodiment.

As shown in fig. 1 and 2, the invention provides an air-conditioning garment, which comprises a wearable device 1, wherein a pipeline 11 is arranged in the wearable device 1, the pipeline 11 is used for supplying water to flow and exchanging heat between water and a human body, the end part of the pipeline 11 is connected with a temperature control system 2, the temperature control system 2 comprises an air-conditioning module 21, and the air-conditioning module 21 is connected with a power supply 22.

The temperature control system 2 adjusts the sensible temperature of the user by reducing or increasing the temperature of the water in the pipeline 11.

Optionally, the air conditioning module 21 includes a compressor 211, a first heat exchanger 212 for exchanging heat with an external environment, a throttling element 213, and a second heat exchanger 214 for exchanging heat with the inside of the air conditioning clothes, the compressor 211 is provided with an air outlet 2111 and an air inlet 2112, and the air outlet 2111, the first heat exchanger 212, the throttling element 213, the second heat exchanger 214, and the air inlet 2112 are connected in sequence.

During cooling, high-pressure vapor discharged from the compressor 211 enters the first heat exchanger 212 through the discharge port 2111, the refrigerant vapor is condensed into liquid, enters the second heat exchanger 214 through the throttling element 213, absorbs heat of water in the pipeline 11 in the second heat exchanger 214, cools the water, and the evaporated refrigerant vapor is sucked by the compressor 211 through the suction port 2112 in a cycle to realize a refrigeration cycle.

Optionally, the air conditioning module 21 further includes a reversing valve 215, the reversing valve 215 is provided with a first interface 2151, a second interface 2152, a third interface 2153, and a fourth interface 2154, the first interface 2151 is connected to the exhaust port 2111, the second interface 2152 is connected to the suction port 2112, the third interface 2153 is connected to the first heat exchanger 212, and the fourth interface 2154 is connected to the second heat exchanger 214.

The reversing valve 215 allows the air conditioning module 21 to both cool and heat. During refrigeration, high-pressure steam discharged by the compressor 211 enters the first heat exchanger 212 through the reversing valve 215, the refrigerant steam is condensed into liquid, enters the second heat exchanger 214 through the throttling element 213, absorbs heat of water in the pipeline 11 in the second heat exchanger 214, cools the water, and the evaporated refrigerant steam is sucked by the compressor 211 after passing through the reversing valve 215, and the refrigeration cycle is repeated.

During heating, high-pressure steam discharged by the compressor 211 enters the second heat exchanger 214 through the reversing valve 215, latent heat released during condensation of refrigerant steam heats water in the pipeline 11, condensed liquid refrigerant flows through the throttling element 213 and then enters the first heat exchanger 212 to absorb external heat for evaporation, and evaporated steam is sucked by the compressor 211 after passing through the reversing valve 215 to complete a heating cycle.

Optionally, the second heat exchanger 214 is provided with a first air pipe connector 2141, a second air pipe connector 2142, a first water pipe connector 2143 and a second water pipe connector 2144, the first air pipe connector 2141 is connected to the fourth connector 2154, and the second air pipe connector 2142 is connected to the throttling element 213; one end of the pipeline 11 is provided with a water inlet 111, the other end is provided with a water outlet 112, the water outlet 112 is connected with the first water pipe connector 2143 through a first connecting pipe 113, and the water inlet 111 is connected with the second water pipe connector 2144 through a second connecting pipe 114.

The water in the pipeline 11 flows out from the water outlet 112, flows into the second heat exchanger 214 through the first connecting pipe 113 to be cooled or heated, and flows out from the second water pipe connector 2144 through the second connecting pipe 114, and flows into the wearable device 1 from the water inlet 111, so that the body sensing temperature of the user is adjusted.

Fig. 3 is a schematic structural diagram of a wearable device according to an example embodiment.

As shown in fig. 3, optionally, the wearable device 1 comprises an inner layer and an outer layer, the tubing 11 being arranged between the inner layer and the outer layer, the inner layer comprising the first solution membrane 12. The first solution film 12 can absorb moisture on the surface of a human body to realize dehumidification; or the moisture is discharged to the surface of the human body, thereby realizing the humidification.

Optionally, a second solution membrane 13 is arranged outside the first heat exchanger 212, the first solution membrane 12 is connected with the second solution membrane 13 through a water pipe 14, and a booster water pump 15 is arranged on the water pipe.

Here, the first solution membrane 12, the second solution membrane 13, the water pipe 14, and the booster water pump 15 together constitute a solution humidity control apparatus.

The solution humidity adjusting device further comprises a voltage adjusting module electrically connected with the power supply 22, and the voltage adjusting module can be used for supplying power to the first solution film 12 and the second solution film 13 so as to realize ionization work of the solution films; meanwhile, the voltage regulating module can also regulate the voltage for supplying power to the first solution membrane 12 and the second solution membrane 13, so that the purpose of regulating the ionization efficiency is achieved, and the dehumidification/humidification efficiency of the solution humidity regulating device can be further controlled.

In summer refrigeration, when the surface of a human body needs to be dehumidified, after the first solution film 12 absorbs moisture on the surface of the human body, the absorbed water flows into the water pipe 14, flows into the second solution film 13 through the booster pump 15, is reduced by the second solution film 13, and is discharged.

When the human body surface needs to be humidified during heating in winter, the second solution film 13 absorbs moisture in the air, and the absorbed water flows into the water pipe 14 and flows into the first solution film 12 through the booster water pump 15, so that the human body surface is humidified.

Optionally, the inner layer further comprises a heat transfer layer 16, the heat transfer layer 16 is arranged on the outer side of the first solution film 12, and the fabric of the heat transfer layer 16 contains silver ions, so that the heat transfer effect of the heat transfer layer 16 can be enhanced, and the rapid heat exchange between the pipeline 11 and the surface of the human body is facilitated.

Optionally, the outer layer comprises an adsorption layer 17, and the outer surface of the adsorption layer 17 is coated with the solar power generation panel. The solar panel can convert light energy into electric energy to supply power to the air conditioning module 21.

Optionally, the outer layer further comprises a heat insulation layer 18, the heat insulation layer 18 is arranged on the inner side of the adsorption layer 17, and the fabric of the heat insulation layer 18 contains aramid fiber. The heat insulation layer 18 can prevent heat exchange between the external environment and the pipeline 11, and improve the utilization rate of heat in the pipeline 11.

Alternatively, the power source 22 is a lithium battery, and the solar panel is connected to the lithium battery through the first output line 171 for charging the lithium battery. The solar power generation panel is connected to the air conditioning module 21 through a second output line 172, and is configured to supply power to the air conditioning module 21. A first switch 173 is arranged on a circuit connecting the lithium battery and the solar power generation panel, a second switch 174 is arranged on a circuit connecting the lithium battery and the air conditioning module 21, and a third switch 175 is arranged on a circuit connecting the solar power generation panel and the air conditioning module 21. The first switch 173, the second switch 174 and the third switch 175 are respectively used for controlling the on/off of the circuit.

When the generated voltage of the solar panel enables the air conditioning module 21 to normally operate, the air conditioning module 21 is powered by the solar panel, the second switch 174 is closed, and the first switch 173 and the third switch 175 are opened. When the generated voltage of the solar panel cannot enable the air conditioning module 21 to normally operate, the power is supplied by the lithium battery, the second switch 174 is closed, and the first switch 173 and the third switch 175 are opened. The solar panel may also charge the lithium battery, and the first switch 173 is closed when the lithium battery is charged.

Optionally, a circulating water pump 115 is disposed on the first connecting pipe 113 or the second connecting pipe 114, and the circulating water pump 115 circulates the water in the pipeline 11 repeatedly, so as to better realize the adjustment of the sensible temperature of the user.

Optionally, a water tank 116 is further disposed on the first connecting pipe 113 or the second connecting pipe 114, and a water replenishing valve 1161 is disposed on a top of the water tank 116. The water tank 116 can prevent the circulating water pump 115 from sucking, and the water in the water tank 116 can be replenished through the water replenishing valve 1161.

Optionally, a pressure release valve 117 is further disposed on the first connecting pipe 113 or the second connecting pipe 114, when the pressure in the pipeline 11 is greater than a set value, the pressure release valve 117 is opened to release the pressure, an altitude at the top of the pressure release valve 117 is higher than an altitude at the top of the water tank 116, only the pressure is released, and water outflow during pressure release is avoided.

Optionally, a first outer fan 2121 and a second outer fan 2122 are arranged outside the first heat exchanger 212, and axial air outlet sides of the first outer fan 2121 and the second outer fan 2122 are arranged toward the first heat exchanger 212 to cool the first heat exchanger 212.

In this embodiment, the rotation speeds of the first external fan 2121 and the second external fan 2122 are controlled by adjusting a set gear, specifically, the set gear of the first external fan 2121 and the second external fan 22 includes a high gear, a medium gear, and a low gear. The specific rotating speed range of each set gear can be adjusted and determined according to the type of the air conditioning clothes and the air supply requirement, and the invention is not limited to this.

Alternatively, the throttling element 213 is a capillary tube, an electronic expansion valve, or a thermal expansion valve.

Fig. 4 is a flowchart illustrating a control method of an air-conditioning suit according to an exemplary embodiment of the present invention.

As shown in fig. 4, the present invention further provides a flow diagram of a control method of an air conditioning garment, and the specific control flow includes:

s401, acquiring running state parameters of the air-conditioning clothes under a refrigeration working condition;

in this embodiment, the initial default operating mode of the air-conditioning clothes is the cooling mode, so that when the air-conditioning clothes is started to operate, the air-conditioning clothes operates in the default cooling mode, and the operation state parameters of the air-conditioning clothes during operation in the cooling mode are detected in step S401;

optionally, when the air-conditioning clothes operate in the default refrigeration mode, the related working components of the air-conditioning clothes, such as the compressor, the circulating water pump and the like, are started according to the initial setting parameters corresponding to the refrigeration mode, such as the set refrigeration working frequency of the compressor and the set refrigeration flow of the circulating water pump, after the air-conditioning clothes are started, a certain time is needed for the related working components to gradually reach the initial setting parameters from 0, and then the air-conditioning clothes stably operate in the operation state corresponding to the setting parameters; therefore, in order to improve the accuracy of controlling the air conditioner clothes, the operation state parameter of the air conditioner clothes under the refrigeration condition obtained in step S401 is a parameter detected by starting the air conditioner clothes and continuously setting the duration, such as 5min and 10 min.

Operating condition parameters include, but are not limited to, external ambient temperature and internal humidity; here, the external ambient temperature is a temperature of an environment in which a user of the air-conditioning suit is located, and the internal humidity is a humidity of an accommodating space of the body of the user formed inside the wearable device of the air-conditioning suit.

Here, the air-conditioning suit is further provided with a temperature sensor which can be used for detecting the temperature of the environment where a user of the air-conditioning suit is located, so as to take the detected temperature as external environment temperature data; and the air-conditioning clothes are also provided with a humidity sensor which can be used for detecting the humidity of the accommodating space of the body of the user formed inside the wearable equipment of the air-conditioning clothes so as to take the detected humidity as internal humidity data.

S402, determining whether preset regulation conditions are met or not based on the running state parameters;

in this embodiment, step S402 is to determine whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity;

the air-conditioning suit is preset with at least six interval threshold values which are sequentially increased and are used for corresponding temperature interval rules representing user feelings including at least cold, low cold, moderate, high heat, hot and extremely hot; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the regulation condition comprises a temperature interval and an interval combination consisting of one or more humidity intervals; or one humidity interval combined with one or more temperature intervals.

In an alternative embodiment, the at least six temperature ranges include Tao ≦ 16 deg.C, 16 ℃ < Tao ≦ 22 deg.C, 22 ℃ < Tao ≦ 29 deg.C, 29 ℃ < Tao ≦ 32 deg.C, 32 ℃ < Tao ≦ 43 deg.C, and T > 43 deg.C for corresponding user experiences including at least cold, low cold, moderate, high heat, hot, and extreme heat, respectively; wherein, Tao refers to the external ambient temperature.

The at least four humidity intervals comprise RH not more than 45%, RH not more than 45% and RH not more than 60% and RH more than 85%, and are respectively used for corresponding user combinations for representing dryness, moderation, low humidity and high humidity; wherein RH refers to internal humidity.

Alternatively, the plurality of temperature intervals and the plurality of humidity intervals may constitute 4 sets of interval combinations of the regulation conditions as shown in table 1.

TABLE 1

Based on table 1, the section combination to which the operating state parameter belongs may be determined by the operating state parameter obtained in step S401, and the operating state of the air conditioner is adjusted according to the regulation rule corresponding to the section combination.

Here, the air-conditioning suit may only preset one regulation condition, which is a set of temperature intervals and humidity intervals; in step S402, the air conditioning clothes may be matched with the regulation condition according to the operation state parameter, and if the matching is successful, the operation state parameter satisfies the regulation condition, and step S403 may be continuously performed; if the matching is unsuccessful, the operation state parameters do not meet the regulation and control conditions, and the control process is finished.

Or, the air conditioner may also preset a plurality of regulation conditions, each regulation condition being a combination of a set of temperature intervals and humidity intervals; in step S402, the air conditioner clothes may be respectively matched with a plurality of control conditions according to the operation state parameters, and step S403 is continuously performed according to a matching result that the matching is successful.

403. Responding to the condition that the operating state parameter meets the preset regulation condition, and adjusting the operating state of the air-conditioning clothes according to the preset regulation rule corresponding to the preset regulation condition;

here, the preset regulation and control rules include, but are not limited to, a frequency regulation rule of the compressor, a flow regulation rule of the circulating water pump, start and stop of the solution humidity control device, and start and stop gear of the two outer fans (the first outer fan and the second outer fan).

Specifically, the frequency adjustment rule for an alternative compressor is shown in table 2:

temperature interval	Setting the frequency: rated frequency coefficient
		Tao≤16℃	0.78*51＝40Hz
16℃<Tao≤22℃	0.96*51＝49Hz
		22℃<Tao≤29℃	1.1*51＝55Hz
29℃<Tao≤32℃	1.2*51＝61Hz
		32℃<Tao≤43℃	1.56*51＝80Hz
Tao＞43℃	0.7*51＝36Hz

TABLE 2

In table 2, the nominal frequency of the compressor is 51, and 0.78, 0.96, 1.1, 1.2, 1.56 and 0.7 are frequency scaling coefficients associated with different temperature intervals; after the operating state parameters are determined to meet the preset regulation and control conditions, the frequency ratio coefficient corresponding to the temperature interval of the regulation and control conditions can be determined in a table look-up mode, and then the set frequency is calculated. And adjusting the working frequency of the compressor from the initial set parameter to the calculated set frequency so as to be matched with the current external environment working condition, and ensuring the comfort requirement of the user on the temperature.

An alternative flow regulation rule for circulating water pumps is shown in table 3:

interval of humidity	Circulating water pump flow: rated flow coefficient
		Tao≤16℃	0.52*0.8＝0.416
16℃<Tao≤22℃	0.96*0.8＝0.768
		22℃<Tao≤29℃	1.15*0.8＝0.92
29℃<Tao≤32℃	1.23*0.8＝0.984
		32℃<Tao≤43℃	1.76*0.8＝1.408
Tao＞43℃	2

TABLE 3

In table 3, the rated flow rate of the circulating water pump is 0.8, and 0.52, 0.96, 1.15, 1.23, and 1.76 are flow rate ratio coefficients associated with different temperature intervals; after the operating state parameters are determined to meet the preset regulation and control conditions, the flow ratio coefficient corresponding to the temperature interval of the regulation and control conditions can be determined in a table look-up mode, and then the flow of the target circulating water pump is calculated. And adjusting the flow of the circulating water pump from the initially set parameter to the calculated target circulating water pump flow so as to be matched with the current external environment working condition, and ensuring the comfort requirement of the user on the temperature.

Hereinafter, a detailed description will be given of a specific control process of the control method of the air conditioning clothes according to the present invention with reference to some specific embodiments.

FIG. 5 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

as shown in fig. 5, the present invention provides another control method of an air conditioning clothes, the control process mainly includes:

s501, acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

in this embodiment, the manner of obtaining the external ambient temperature and the internal humidity may refer to step S401 in the foregoing embodiment, which is not described herein again.

S502, judging whether the external environment temperature is in a preset temperature interval for representing that the user feels cold, and if so, executing a step S503; if not, the process is ended;

in the embodiment, the preset temperature interval for representing that the user feels cold is Tao less than or equal to 16 ℃;

thus, when the detected external environment temperature is the temperature values of 0 ℃, 7 ℃ and 15 ℃, and the external environment temperature is not greater than the interval threshold value 16 ℃ representing the temperature interval in which the user feels cold, it is determined that the external environment temperature is in the preset temperature interval in which the user feels cold, and the step S503 is continuously executed; and when the detected external environment temperature is the temperature values of 18 ℃, 22 ℃, 30 ℃ and the like, and the external environment temperature is greater than the interval threshold value 16 ℃ representing the temperature interval in which the user feels cold, judging that the external environment temperature is not in the preset temperature interval for representing the temperature interval in which the user feels cold, and ending the process.

S503, judging whether the internal humidity is in a preset humidity interval for representing that the user feels moderate, if so, executing a step S504; if not, the process is ended;

in the embodiment, the preset humidity interval for representing that the user feels moderate is 45% < RH ≦ 60%;

thus, when the detected internal humidity is at the humidity values of 46%, 53%, 60%, etc., it is determined that the internal humidity is within the preset humidity range for representing that the user feels moderate, and the step S504 is continuously performed; and when the detected internal humidity is the humidity values of 32%, 72%, 81% and the like, judging that the internal humidity is not in a preset humidity range for representing that the user feels moderate, and ending the process.

Here, the preset regulation condition includes that the external environment temperature is in a preset temperature interval for representing that the user feels cold in step S502, and the internal humidity is in a preset humidity interval for representing that the user feels moderate in step S503;

s504, responding to the external environment temperature and the internal humidity, determining that a preset regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the preset regulation condition;

when the external environment temperature is in a preset temperature range for representing that a user feels cold and the internal humidity is in a preset humidity range for representing that the user feels moderate, the regulation and control rule comprises the steps that the compressor and the circulating water pump operate according to set parameters, the solution humidity control device is controlled to operate at the lowest working voltage of the dehumidification mode, the first external fan operates at a low wind level, and the second external fan stops operating.

Specifically, the setting parameters of the compressor include a setting frequency, and the setting frequency is calculated according to the following formula: f is F K1, where F is the set frequency and F is the rated operating frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.78.

In the present embodiment, when the rated operating frequency of the compressor is 51Hz, the set frequency f is calculated to be 51 × 0.78 ≈ 40Hz according to the above formula.

The set parameters of the circulating water pump comprise set flow, and the set flow is calculated according to the following formula: q is Q K2, wherein Q is the set flow rate, and Q is the rated flow rate of the circulating water pump; k2 is a flow rate ratio coefficient associated with the regulation condition, which takes a value of 0.52.

In this embodiment, when the rated flow rate of the circulating water pump is 0.8L/min, the set flow rate q is 0.8 × 0.52 — 0.416L/min calculated according to the above formula.

In the embodiment, because the optimal humidity range for the human body is 45% -60%, the inside of the air conditioning clothes does not need to be dehumidified under the current working condition; however, considering that adverse factors such as poor ventilation conditions may exist in the external environment where the user is located, in order to reduce the occurrence of situations such as small heat exchange difference and low heat exchange amount of the first heat exchanger due to the adverse factors, the solution humidity control device is controlled to operate the dehumidification mode at the lowest working voltage, and at this time, the first solution film can absorb water vapor inside the air-conditioning clothes and convey the water vapor to the second solution film; the second solution membrane can analyze and evaporate part of water so as to cool the first heat exchanger, thereby improving the heat exchange effect of the first heat exchanger; at this time, the solution is driven by the booster pump at a low flow rate to perform the reduction outside the circulation chamber.

Here, the voltage value applied to the first solution film by the solution humidity control apparatus and the dehumidification amount thereof should satisfy the following relationship:

q2 ═ 0.25 × U2-2, where Q2 is the dehumidification amount of the first solution film, and U2 is the voltage value applied to the first solution film; in this embodiment, U2 is 12V.

The flow of the booster water pump is calculated according to the following formula:

q2 ═ K2 r, where q2 is the flow rate of the booster water pump; r is the rotating speed of the booster water pump, and the value range of r is 100-1000 rpm; k2 is the ratio coefficient of the associated booster water pump.

In this embodiment, first outer fan is with the operation of low-wind-level, the outer fan shutdown of second, can satisfy the amount of wind requirement that first heat exchanger and outdoor environment carry out the heat transfer, has also reduced the whole energy consumption of outer fan operation simultaneously, and is energy-concerving and environment-protective.

In an optional embodiment, the control method further comprises: acquiring the current working voltage in a control circuit of the air-conditioning clothes; and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

Here, the power supply mode of the air-conditioning clothes of the present invention includes a battery power supply mode and a standby power supply mode of the air-conditioning clothes; the power supply arranged on the air-conditioning clothes comprises a solar power generation panel and a lithium battery, wherein the solar power generation panel is arranged on the wearable equipment and is used for supplying power to all power-requiring components of the air-conditioning clothes in an electric power supply mode of the air-conditioning clothes, and the lithium battery is used for supplying power to all power-requiring components of the air-conditioning clothes in a standby power supply mode. The default power supply of the air-conditioning clothes is the solar power generation panel, and the default power supply mode is the power supply mode of the air-conditioning clothes; the air conditioning clothes can be ensured to continuously work for a long time by arranging the two groups of power supplies so as to meet the operation requirements of users.

Optionally, the preset voltage condition is that the working voltage is not lower than a set voltage value; if the current working voltage is lower than the set voltage value, judging that the current working voltage does not meet the preset voltage condition; and if the current working voltage is not lower than the set voltage value, judging that the current working voltage meets the preset voltage condition, and supplying power to related components by the air-conditioning clothes in a battery power supply mode of the air-conditioning clothes.

The electric quantity stored in the battery of the air-conditioning clothes is a limited electric quantity value, the actual working voltage in the control circuit of the air-conditioning clothes is in a gradually-reduced state along with the prolonging of the service time of the air-conditioning clothes, when the bottom of the working mat is lower than a set voltage value, the working efficiency of the electricity-requiring components is reduced, such as the running frequency of a compressor is reduced, and the like, so that the refrigerating/heating efficiency of the air-conditioning clothes is easily influenced.

Specifically, for the air-conditioning clothes shown in the foregoing embodiments, the specific process of controlling the switching from the power supply mode of the air-conditioning clothes to the standby power supply mode includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

FIG. 6 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

as shown in fig. 6, the present invention provides another control method of an air conditioning clothes, the control process mainly includes:

s601, acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

in this embodiment, the manner of obtaining the external ambient temperature and the internal humidity may refer to step S401 in the foregoing embodiment, which is not described herein again.

S602, judging whether the external environment temperature is in a preset temperature interval for representing that the user feels cold, and if so, executing a step S603; if not, the process is ended;

in the embodiment, the preset temperature range for representing that the user feels low cold is 16 ℃ < Tao ≦ 22 ℃;

the specific process of determining whether the external environment temperature is in the preset temperature interval for representing that the user feels cold may refer to the foregoing embodiments, which are not described herein again.

S603, judging whether the internal humidity is in a preset humidity interval for representing that the user feels moderate, and if so, executing a step S604; if not, the process is ended;

in the embodiment, the preset humidity interval for representing that the user feels moderate is 45% < RH ≦ 60%;

the specific process of determining whether the internal humidity is within the preset humidity interval for representing that the user feels moderate may refer to the foregoing embodiments, which are not described herein again.

Here, the preset regulation condition includes that the external environment temperature is in a preset temperature interval for representing that the user feels low cold in step S602, and the internal humidity is in a preset humidity interval for representing that the user feels moderate in step S603;

s604, responding to the external environment temperature and the internal humidity, determining that a preset regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the preset regulation condition;

here, when the external environment temperature is in a preset temperature range for representing that the user feels low cold and the internal humidity is in a preset humidity range for representing that the user feels moderate, the regulation and control rule includes that the compressor and the circulating water pump operate according to set parameters, the solution humidity control device is controlled to operate at the lowest working voltage of the dehumidification mode, the first external fan operates at a medium wind gear, and the second external fan stops operating.

Specifically, the setting parameters of the compressor include a setting frequency, and the setting frequency is calculated according to the following formula: f is F K1, where F is the set frequency and F is the rated operating frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.96.

In the present embodiment, when the rated operating frequency of the compressor is 51Hz, the set frequency f is calculated to be 51 × 0.96 ≈ 49Hz according to the above formula.

The set parameters of the circulating water pump comprise set flow, and the set flow is calculated according to the following formula: q is Q K2, wherein Q is the set flow rate, and Q is the rated flow rate of the circulating water pump; k2 is a flow rate sequence coefficient associated with the regulation condition, and its value is 0.96.

In the present embodiment, when the rated flow rate of the circulating water pump is 0.8L/min, the set flow rate q is 0.8 × 0.96 — 0.768L/min calculated according to the above formula.

In the embodiment, because the optimal humidity range for the human body is 45% -60%, the inside of the air conditioning clothes does not need to be dehumidified under the current working condition; however, considering that adverse factors such as poor ventilation conditions may exist in the external environment where the user is located, in order to reduce the occurrence of situations such as small heat exchange difference and low heat exchange amount of the first heat exchanger due to the adverse factors, the solution humidity control device is controlled to operate the dehumidification mode at the lowest working voltage, and at this time, the first solution film can absorb water vapor inside the air-conditioning clothes and convey the water vapor to the second solution film; the second solution membrane can analyze and evaporate part of water so as to cool the first heat exchanger, thereby improving the heat exchange effect of the first heat exchanger; at this time, the solution is driven by the booster pump at a low flow rate to perform the reduction outside the circulation chamber.

Here, the voltage value applied to the first solution film by the solution humidity control apparatus and the dehumidification amount thereof should satisfy the following relationship:

q2 ═ 0.25 × U2-2, where Q2 is the dehumidification amount of the first solution film, and U2 is the voltage value applied to the first solution film; in this embodiment, U2 is 12V.

The flow of the booster water pump is calculated according to the following formula:

q2 ═ K2 r, where q2 is the flow rate of the booster water pump; r is the rotating speed of the booster water pump, and the value range of r is 100-1000 rpm; k2 is the ratio coefficient of the associated booster water pump.

In this embodiment, first outer fan is with middle wind gear operation, the outer fan bring to rest of second, can satisfy the amount of wind requirement that first heat exchanger and outdoor environment carry out the heat transfer, has also reduced the whole energy consumption of outer fan operation simultaneously, and is energy-concerving and environment-protective.

In an optional embodiment, the control method further comprises: acquiring the current working voltage in a control circuit of the air-conditioning clothes; and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

For the air-conditioning clothes shown in the foregoing embodiments, the process of controlling the switching from the power supply mode of the air-conditioning clothes to the standby power supply mode includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

For the specific power supply mode switching process, reference may be made to the previous embodiment, which is not described herein again.

FIG. 7 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

as shown in fig. 7, the present invention provides another control method of an air conditioning clothes, the control process mainly includes:

s701, acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

in this embodiment, the manner of obtaining the external ambient temperature and the internal humidity may refer to step S401 in the foregoing embodiment, which is not described herein again.

S702, judging whether the external environment temperature is in a preset temperature range for representing that a user feels moderate, and if so, executing a step S703; if not, the process is ended;

in the embodiment, the preset temperature range for representing that the user feels moderate is 22 ℃ < Tao ≦ 29 ℃;

the specific process of determining whether the external environment temperature is within the preset temperature range for representing that the user feels moderate may refer to the foregoing embodiments, which are not described herein again.

S703, judging whether the internal humidity is in a preset humidity interval for representing that the user feels moderate, if so, executing S704; if not, the process is ended;

in the embodiment, the preset humidity interval for representing that the user feels moderate is 45% < RH ≦ 60%;

the specific process of determining whether the internal humidity is within the preset humidity interval for representing that the user feels moderate may refer to the foregoing embodiments, which are not described herein again.

Here, the preset regulation condition includes that the external environment temperature is in a preset temperature interval for representing that the user feels moderate in step S702, and the internal humidity is in a preset humidity interval for representing that the user feels moderate in step S703;

s704, responding to the external environment temperature and the internal humidity, determining that a preset regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the preset regulation condition;

when the external environment temperature is in a preset temperature range for representing that a user feels moderate and the internal humidity is in a preset humidity range for representing that the user feels moderate, the regulation and control rule comprises the steps that the compressor and the circulating water pump operate according to set parameters, the solution humidity control device is controlled to operate at the lowest working voltage of the dehumidification mode, the first external fan operates at a high wind level, and the second external fan stops operating.

Specifically, the setting parameters of the compressor include a setting frequency, and the setting frequency is calculated according to the following formula: f is F K1, where F is the set frequency and F is the rated operating frequency of the compressor; k1 is a frequency scaling coefficient associated with the regulation condition, and its value is 1.1.

In the present embodiment, when the rated operating frequency of the compressor is 51Hz, the set frequency f is calculated to be 51 × 1.1 ≈ 55Hz according to the above formula.

The set parameters of the circulating water pump comprise set flow, and the set flow is calculated according to the following formula: q is Q K2, wherein Q is the set flow rate, and Q is the rated flow rate of the circulating water pump; k2 is a flow rate series coefficient associated with the regulation condition, and its value is 1.15.

In this embodiment, when the rated flow rate of the circulating water pump is 0.8L/min, the set flow rate q is 0.8 × 1.15 — 0.92L/min calculated according to the above formula.

In the embodiment, because the optimal humidity range for the human body is 45% -60%, the inside of the air conditioning clothes does not need to be dehumidified under the current working condition; however, considering that adverse factors such as poor ventilation conditions may exist in the external environment where the user is located, in order to reduce the occurrence of situations such as small heat exchange difference and low heat exchange amount of the first heat exchanger due to the adverse factors, the solution humidity control device is controlled to operate the dehumidification mode at the lowest working voltage, and at this time, the first solution film can absorb water vapor inside the air-conditioning clothes and convey the water vapor to the second solution film; the second solution membrane can analyze and evaporate part of water so as to cool the first heat exchanger, thereby improving the heat exchange effect of the first heat exchanger; at this time, the solution is driven by the booster pump at a low flow rate to perform the reduction outside the circulation chamber.

Here, the voltage value applied to the first solution film by the solution humidity control apparatus and the dehumidification amount thereof should satisfy the following relationship:

q2 ═ 0.25 × U2-2, where Q2 is the dehumidification amount of the first solution film, and U2 is the voltage value applied to the first solution film; in this embodiment, U2 is 12V.

The flow of the booster water pump is calculated according to the following formula:

q2 ═ K2 r, where q2 is the flow rate of the booster water pump; r is the rotating speed of the booster water pump, and the value range of r is 100-1000 rpm; k2 is the ratio coefficient of the associated booster water pump.

In this embodiment, first outer fan is with high-wind-gear operation, the outer fan shutdown of second, can satisfy the amount of wind requirement that first heat exchanger and outdoor environment carry out the heat transfer, has also reduced the whole energy consumption of outer fan operation simultaneously, and is energy-concerving and environment-protective.

In an optional embodiment, the control method further comprises: acquiring the current working voltage in a control circuit of the air-conditioning clothes; and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

For the air-conditioning clothes shown in the foregoing embodiments, the process of controlling the switching from the power supply mode of the air-conditioning clothes to the standby power supply mode includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

For the specific power supply mode switching process, reference may be made to the previous embodiment, which is not described herein again.

FIG. 8 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

as shown in fig. 8, the present invention provides another control method of an air conditioning clothes, the control process mainly includes:

s801, acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

in this embodiment, the manner of obtaining the external ambient temperature and the internal humidity may refer to step S401 in the foregoing embodiment, which is not described herein again.

S802, judging whether the external environment temperature is in a preset temperature interval for representing that a user feels high heat, and if so, executing a step S803; if not, the process is ended;

in the embodiment, the preset temperature range for representing that the user feels high heat is 29 ℃ < Tao ≦ 32 ℃;

for a specific process of determining whether the external environment temperature is in the preset temperature interval for representing that the user feels high heat, reference may be made to the foregoing embodiments, which are not described herein again.

S803, judging whether the internal humidity is in a preset humidity interval for representing that the user feels moderate, if so, executing step S804; if not, the process is ended;

in the embodiment, the preset humidity interval for representing that the user feels moderate is 45% < RH ≦ 60%;

the specific process of determining whether the internal humidity is within the preset humidity interval for representing that the user feels moderate may refer to the foregoing embodiments, which are not described herein again.

Here, the preset regulation condition includes that the external environment temperature is in a preset temperature interval for representing that the user feels high heat in step S802, and the internal humidity is in a preset humidity interval for representing that the user feels moderate heat in step S803;

s804, responding to the external environment temperature and the internal humidity, determining that a preset regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the preset regulation condition;

here, when the external environment temperature is in a preset temperature range for representing that the user feels high heat and the internal humidity is in a preset humidity range for representing that the user feels moderate heat, the regulation and control rule includes that the compressor and the circulating water pump operate according to set parameters, the solution humidity control device is controlled to operate at the lowest working voltage of the dehumidification mode, the first external fan operates at a high wind level, and the second external fan operates at a low wind level.

Specifically, the setting parameters of the compressor include a setting frequency, and the setting frequency is calculated according to the following formula: f is F K1, where F is the set frequency and F is the rated operating frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, and its value is 1.2.

In the present embodiment, when the rated operating frequency of the compressor is 51Hz, the set frequency f is calculated according to the above formula to be 51 × 1.2 ≈ 61 Hz.

The set parameters of the circulating water pump comprise set flow, and the set flow is calculated according to the following formula: q is Q K2, wherein Q is the set flow rate, and Q is the rated flow rate of the circulating water pump; k2 is a flow rate series coefficient associated with the regulation condition, and its value is 1.23.

In this embodiment, when the rated flow rate of the circulating water pump is 0.8L/min, the set flow rate q is 0.8 × 1.23 — 0.984L/min calculated according to the above formula.

In the embodiment, because the optimal humidity range for the human body is 45% -60%, the inside of the air conditioning clothes does not need to be dehumidified under the current working condition; however, considering that adverse factors such as poor ventilation conditions may exist in the external environment where the user is located, in order to reduce the occurrence of situations such as small heat exchange difference and low heat exchange amount of the first heat exchanger due to the adverse factors, the solution humidity control device is controlled to operate the dehumidification mode at the lowest working voltage, and at this time, the first solution film can absorb water vapor inside the air-conditioning clothes and convey the water vapor to the second solution film; the second solution membrane can analyze and evaporate part of water so as to cool the first heat exchanger, thereby improving the heat exchange effect of the first heat exchanger; at this time, the solution is driven by the booster pump at a low flow rate to perform the reduction outside the circulation chamber.

Here, the voltage value applied to the first solution film by the solution humidity control apparatus and the dehumidification amount thereof should satisfy the following relationship:

q2 ═ 0.25 × U2-2, where Q2 is the dehumidification amount of the first solution film, and U2 is the voltage value applied to the first solution film; in this embodiment, U2 is 12V.

The flow of the booster water pump is calculated according to the following formula:

q2 ═ K2 r, where q2 is the flow rate of the booster water pump; r is the rotating speed of the booster water pump, and the value range of r is 100-1000 rpm; k2 is the ratio coefficient of the associated booster water pump.

In this embodiment, first outer fan is with high-wind-gear operation, the outer fan of second is with low-wind-gear operation, can satisfy the amount of wind requirement that first heat exchanger and outdoor environment carry out the heat transfer, has also reduced the whole energy consumption of outer fan operation simultaneously, and is energy-concerving and environment-protective.

In an optional embodiment, the control method further comprises: acquiring the current working voltage in a control circuit of the air-conditioning clothes; and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

For the air-conditioning clothes shown in the foregoing embodiments, the process of controlling the switching from the power supply mode of the air-conditioning clothes to the standby power supply mode includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

For the specific power supply mode switching process, reference may be made to the previous embodiment, which is not described herein again.

FIG. 9 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

as shown in fig. 9, the present invention provides another control method of an air conditioning clothes, the control process mainly includes:

s901, acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

in this embodiment, the manner of obtaining the external ambient temperature and the internal humidity may refer to step S401 in the foregoing embodiment, which is not described herein again.

S902, judging whether the external environment temperature is in a preset temperature interval for representing that the user feels hot, and if so, executing a step S903; if not, the process is ended;

in the embodiment, the preset temperature interval for representing that the user feels hot is 32 ℃ < Tao ≦ 43 ℃;

the specific process of determining whether the external environment temperature is in the preset temperature interval for representing that the user feels hot may refer to the foregoing embodiments, which are not described herein again.

S903, judging whether the internal humidity is in a preset humidity interval for representing that a user feels moderate, and if so, executing a step S904; if not, the process is ended;

in the embodiment, the preset humidity interval for representing that the user feels moderate is 45% < RH ≦ 60%;

the specific process of determining whether the internal humidity is within the preset humidity interval for representing that the user feels moderate may refer to the foregoing embodiments, which are not described herein again.

Here, the preset regulation condition includes that the external environment temperature is in a preset temperature interval for representing that the user feels hot in step S902, and the internal humidity is in a preset humidity interval for representing that the user feels moderate in step S903;

s904, responding to the external environment temperature and the internal humidity, determining that a preset regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the preset regulation condition;

here, when the external environment temperature is in a preset temperature range for representing that the user feels hot and the internal humidity is in a preset humidity range for representing that the user feels moderate, the regulation and control rule includes that the compressor and the circulating water pump operate according to set parameters, the solution humidity control device is controlled to operate at the lowest working voltage of the dehumidification mode, the first external fan operates at a high wind level, and the second external fan operates at a medium wind level.

Specifically, the setting parameters of the compressor include a setting frequency, and the setting frequency is calculated according to the following formula: f is F K1, where F is the set frequency and F is the rated operating frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 1.56.

In the present embodiment, when the rated operating frequency of the compressor is 51Hz, the set frequency f is calculated to be 51 × 1.56 ≈ 80Hz according to the above formula.

The set parameters of the circulating water pump comprise set flow, and the set flow is calculated according to the following formula: q is Q K2, wherein Q is the set flow rate, and Q is the rated flow rate of the circulating water pump; k2 is a flow rate series coefficient associated with the regulation condition, and its value is 1.76.

In this embodiment, when the rated flow rate of the circulating water pump is 0.8L/min, the set flow rate q is calculated according to the above formula to be 0.8 × 1.76 — 1.408L/min.

In the embodiment, because the optimal humidity range for the human body is 45% -60%, the inside of the air conditioning clothes does not need to be dehumidified under the current working condition; however, considering that adverse factors such as poor ventilation conditions may exist in the external environment where the user is located, in order to reduce the occurrence of situations such as small heat exchange difference and low heat exchange amount of the first heat exchanger due to the adverse factors, the solution humidity control device is controlled to operate the dehumidification mode at the lowest working voltage, and at this time, the first solution film can absorb water vapor inside the air-conditioning clothes and convey the water vapor to the second solution film; the second solution membrane can analyze and evaporate part of water so as to cool the first heat exchanger, thereby improving the heat exchange effect of the first heat exchanger; at this time, the solution is driven by the booster pump at a low flow rate to perform the reduction outside the circulation chamber.

Here, the voltage value applied to the first solution film by the solution humidity control apparatus and the dehumidification amount thereof should satisfy the following relationship:

q2 ═ 0.25 × U2-2, where Q2 is the dehumidification amount of the first solution film, and U2 is the voltage value applied to the first solution film; in this embodiment, U2 is 12V.

The flow of the booster water pump is calculated according to the following formula:

q2 ═ K2 r, where q2 is the flow rate of the booster water pump; r is the rotating speed of the booster water pump, and the value range of r is 100-1000 rpm; k2 is the ratio coefficient of the associated booster water pump.

In this embodiment, first outer fan is with high wind gear operation, the outer fan of second is with middle wind gear operation, can satisfy the amount of wind requirement that first heat exchanger and outdoor environment carry out the heat transfer, has also reduced the whole energy consumption of outer fan operation simultaneously, and is energy-concerving and environment-protective.

In an optional embodiment, the control method further comprises: acquiring the current working voltage in a control circuit of the air-conditioning clothes; and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

For the air-conditioning clothes shown in the foregoing embodiments, the process of controlling the switching from the power supply mode of the air-conditioning clothes to the standby power supply mode includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

For the specific power supply mode switching process, reference may be made to the previous embodiment, which is not described herein again.

FIG. 10 is a schematic flow chart diagram illustrating a method of controlling an air conditioning garment of the present invention according to yet another exemplary embodiment;

as shown in fig. 10, the present invention provides another control method of an air conditioning clothes, the control process mainly includes:

s1001, acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

in this embodiment, the manner of obtaining the external ambient temperature and the internal humidity may refer to step S401 in the foregoing embodiment, which is not described herein again.

S1002, judging whether the external environment temperature is in a preset temperature interval for representing that a user feels extremely hot, and if so, executing a step S1003; if not, the process is ended;

in the embodiment, the preset temperature interval for representing that the user feels extremely hot is 43 ℃ < Tao;

for a specific process of determining whether the external environment temperature is in the preset temperature interval for representing that the user feels extremely hot, reference may be made to the foregoing embodiments, which are not described herein again.

S1003, judging whether the internal humidity is in a preset humidity interval for representing that a user feels moderate, if so, executing a step S1004; if not, the process is ended;

in the embodiment, the preset humidity interval for representing that the user feels moderate is 45% < RH ≦ 60%;

the specific process of determining whether the internal humidity is within the preset humidity interval for representing that the user feels moderate may refer to the foregoing embodiments, which are not described herein again.

Here, the preset regulation condition includes that the external environment temperature is in a preset temperature interval for representing that the user feels extremely hot in step S1002, and the internal humidity is in a preset humidity interval for representing that the user feels moderate in step S1003;

s1004, responding to the external environment temperature and the internal humidity, determining that a preset regulation condition is met, and adjusting the running state of the air-conditioning clothes according to a preset regulation rule corresponding to the preset regulation condition;

here, when the external environment temperature is in a preset temperature range for representing that a user feels extremely hot and the internal humidity is in a preset humidity range for representing that the user feels moderate, the regulation and control rule includes that the compressor and the circulating water pump operate according to set parameters, the solution humidity control device is controlled to operate at the lowest working voltage of the dehumidification mode, the first external fan operates at a high wind level, and the second external fan operates at a high wind level.

Specifically, the setting parameters of the compressor include a setting frequency, and the setting frequency is calculated according to the following formula: f is F K1, where F is the set frequency and F is the rated operating frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.7.

In the present embodiment, when the rated operating frequency of the compressor is 51Hz, the set frequency f is calculated to be 51 × 0.7 ≈ 36Hz according to the above formula. In this embodiment, since the circulating water pump is operated at the maximum flow rate, the set frequency of the compressor can be appropriately reduced to 0.7 times of the rated frequency, so as to reduce the power consumption of the compressor.

Meanwhile, the set parameters of the water pump comprise a set flow, wherein the set flow is the maximum flow value of the water pump; in this embodiment, the maximum flow rate of the water pump is 2L/min.

In the embodiment, because the optimal humidity range for the human body is 45% -60%, the inside of the air conditioning clothes does not need to be dehumidified under the current working condition; however, considering that adverse factors such as poor ventilation conditions may exist in the external environment where the user is located, in order to reduce the occurrence of situations such as small heat exchange difference and low heat exchange amount of the first heat exchanger due to the adverse factors, the solution humidity control device is controlled to operate the dehumidification mode at the lowest working voltage, and at this time, the first solution film can absorb water vapor inside the air-conditioning clothes and convey the water vapor to the second solution film; the second solution membrane can analyze and evaporate part of water so as to cool the first heat exchanger, thereby improving the heat exchange effect of the first heat exchanger; at this time, the solution is driven by the booster pump at a low flow rate to perform the reduction outside the circulation chamber.

Here, the voltage value applied to the first solution film by the solution humidity control apparatus and the dehumidification amount thereof should satisfy the following relationship:

q2 ═ 0.25 × U2-2, where Q2 is the dehumidification amount of the first solution film, and U2 is the voltage value applied to the first solution film; in this embodiment, U2 is 12V.

The flow of the booster water pump is calculated according to the following formula:

q2 ═ K2 r, where q2 is the flow rate of the booster water pump; r is the rotating speed of the booster water pump, and the value range of r is 100-1000 rpm; k2 is the ratio coefficient of the associated booster water pump.

In this embodiment, first outer fan is with high-grade operation, the outer fan of second is with high-grade operation, and two outer fans all operate with highest gear, make outer fan can dispel the heat the cooling to first heat exchanger with the maximum air output to furthest's the requirement of satisfying the amount of wind that first heat exchanger and outdoor environment carry out the heat transfer.

In an optional embodiment, the control method further comprises: acquiring the current working voltage in a control circuit of the air-conditioning clothes; and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

For the air-conditioning clothes shown in the foregoing embodiments, the process of controlling the switching from the power supply mode of the air-conditioning clothes to the standby power supply mode includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

For the specific power supply mode switching process, reference may be made to the previous embodiment, which is not described herein again.

In an alternative embodiment, the air conditioning garment further comprises a controller, which may be used to control the control flow disclosed in the embodiment of fig. 4 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for: acquiring running state parameters of the air-conditioning clothes under a refrigeration working condition; determining whether a preset regulation condition is met or not based on the operation state parameter; and responding to the condition that the running state parameters meet the preset regulation and control conditions, and regulating the running state of the air-conditioning clothes according to the preset regulation and control rules corresponding to the preset regulation and control conditions.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the air conditioning garment further comprises a controller operable to control the control flow disclosed in the embodiment of fig. 5 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels cold, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps of controlling the solution humidity control device to operate at the lowest working voltage of a dehumidification mode, controlling the compressor and the water pump to operate according to set parameters, controlling the first outer fan to operate at a low wind level, and controlling the second outer fan to stop operating.

In this embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In this embodiment, the controller is specifically configured to: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In this embodiment, the setting parameter of the compressor includes a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.78.

In this embodiment, the setting parameter of the water pump includes a setting flow rate, and the controller calculates the setting flow rate according to the following formula:

q＝Q*K2，

wherein Q is set flow, and Q is rated flow of the water pump; k2 is a flow rate ratio coefficient associated with the regulation condition, which takes a value of 0.52.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the air conditioning garment further comprises a controller operable to control the control flow disclosed in the embodiment of fig. 6 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels low cold, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the water pump operate according to set parameters, the first outer fan operates at a medium wind gear, and the second outer fan stops operating.

In this embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In this embodiment, the controller is specifically configured to:

and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In this embodiment, the setting parameter of the compressor includes a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.96.

In this embodiment, the setting parameter of the water pump includes a setting flow rate, and the controller calculates the setting flow rate according to the following formula:

q＝Q*K2，

wherein Q is set flow, and Q is rated flow of the water pump; k2 is a flow rate sequence coefficient associated with the regulation condition, and its value is 0.96.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the air conditioning garment further comprises a controller operable to control the control flow disclosed in the embodiment of fig. 7 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels moderate, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps of controlling the solution humidity control device to operate at the lowest working voltage of a dehumidification mode, controlling the compressor and the water pump to operate according to set parameters, controlling the first outer fan to operate at a high wind level, and controlling the second outer fan to stop operating.

In this embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In this embodiment, the controller is specifically configured to:

and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In this embodiment, the setting parameter of the compressor includes a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling coefficient associated with the regulation condition, and its value is 1.1.

In this embodiment, the setting parameter of the water pump includes a setting flow rate, and the controller calculates the setting flow rate according to the following formula:

q＝Q*K2，

wherein Q is set flow, and Q is rated flow of the water pump; k2 is a flow rate series coefficient associated with the regulation condition, and its value is 1.15.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the air conditioning garment further comprises a controller that can be used to control the control flow disclosed in the embodiment of fig. 8 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is configured to:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external ambient temperature and the internal humidity; the preset regulation and control conditions comprise that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the external environment temperature is in a preset temperature range for representing that a user feels high heat, and the internal humidity is in a preset humidity range for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises that the compressor and the water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a low wind gear.

In this embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In this embodiment, the controller is specifically configured to:

and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In this embodiment, the setting parameter of the compressor includes a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is the set frequency, and F is the rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, and its value is 1.2.

In this embodiment, the setting parameter of the water pump includes a setting flow rate, and the controller calculates the setting flow rate according to the following formula:

q＝Q*K2，

wherein Q is the set flow, and Q is the rated flow of the water pump; k2 is a flow rate ratio coefficient associated with the regulation condition, and its value is 1.23.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the air conditioning garment further comprises a controller operable to control the control flow disclosed in the embodiment of fig. 9 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels hot, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a medium wind gear.

In this embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In this embodiment, the controller is specifically configured to:

and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In this embodiment, the setting parameter of the compressor includes a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 1.56.

In this embodiment, the setting parameter of the water pump includes a setting flow rate, and the controller calculates the setting flow rate according to the following formula:

q＝Q*K2，

wherein Q is set flow, and Q is rated flow of the water pump; k2 is a flow rate series coefficient associated with the regulation condition, and its value is 1.76.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

In yet another alternative embodiment, the air conditioning garment further comprises a controller that can be used to control the control flow disclosed in the embodiment of fig. 10 above.

The controller is preset with at least six temperature interval rules which are sequentially increased and used for corresponding representations at least comprising the temperature interval rules of cold, low cold, moderate, high heat, hot and extremely hot user feelings; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is used for:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external environment temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels extremely hot, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a high wind gear.

In this embodiment, the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

In this embodiment, the controller is specifically configured to:

and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

In this embodiment, the setting parameter of the compressor includes a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is a set frequency, and F is a rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, which takes on a value of 0.7.

In this embodiment, the setting parameter of the water pump includes a set flow rate, and the set flow rate is a maximum flow rate value of the water pump.

The specific manner in which the controller controls the above process can refer to the foregoing embodiments, and is not described herein again.

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

Claims (10)

1. The control method of the air conditioning clothes is characterized in that the air conditioning clothes comprise wearable equipment and a temperature control system, wherein a pipeline for supplying water to flow and exchanging heat with a human body is arranged in the wearable equipment, and a circulating water pump for circulating the water in the pipeline is arranged on the pipeline; the temperature control system is used for reducing or increasing the temperature of water in the pipeline, the temperature control system comprises an air conditioning module connected with the pipeline, the air conditioning module comprises a compressor, a first heat exchanger used for exchanging heat with the external environment, a throttling element and a second heat exchanger used for exchanging heat with the inside of the air conditioning clothes, and a first outer fan and a second outer fan used for radiating heat for the first heat exchanger are arranged at the first heat exchanger; the air-conditioning clothes also comprise a temperature sensor for detecting the temperature of the external environment and a humidity sensor for detecting the internal humidity; the air conditioning clothes also comprise a solution humidifying device for adjusting the humidity inside the air conditioning clothes;

the air-conditioning coat is preset with at least six interval threshold values which are sequentially increased and used for corresponding temperature interval rules representing user feelings at least including cold, low cold, moderate, high heat, hot and extremely hot; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the control method comprises the following steps:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external ambient temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels extremely hot, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the circulating water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a high wind gear.

2. The control method according to claim 1, characterized by further comprising:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

3. The control method according to claim 2, wherein the air conditioning clothes further comprise a power supply, the power supply comprises a solar power generation panel and a lithium battery, and the solar power generation panel is connected with the lithium battery through a first output line and is used for charging the lithium battery; the solar power generation panel is connected with the air conditioning module through a second output line and used for supplying power to the air conditioning module; a first switch is arranged on a circuit for connecting the lithium battery and the solar power generation panel, a second switch is arranged on a circuit for connecting the lithium battery and the air conditioning module, and a third switch is arranged on a circuit for connecting the solar power generation panel and the air conditioning module; the first switch, the second switch and the third switch are respectively used for controlling the on-off of the circuit;

the control switches from air conditioner clothing battery power supply mode to standby power supply mode, includes: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

4. The control method as set forth in claim 1, wherein said set parameter of said compressor includes a set frequency, said set frequency being calculated according to the following formula:

f＝F*K1，

wherein F is the set frequency, and F is the rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, and its value is 0.7.

5. The control method according to claim 1 or 4, characterized in that the set parameter of the circulation water pump includes a set flow rate, which is a maximum flow rate value of the circulation water pump.

6. The air conditioning clothes are characterized by comprising wearable equipment and a temperature control system, wherein a pipeline for supplying water to flow and exchanging heat with a human body is arranged in the wearable equipment, and a circulating water pump for circulating the water in the pipeline is arranged on the pipeline; the temperature control system is used for reducing or increasing the temperature of water in the pipeline, the temperature control system comprises an air conditioning module connected with the pipeline, the air conditioning module comprises a compressor, a first heat exchanger used for exchanging heat with the external environment, a throttling element and a second heat exchanger used for exchanging heat with the inside of the air conditioning clothes, and a first outer fan and a second outer fan used for radiating heat for the first heat exchanger are arranged at the first heat exchanger; the air-conditioning clothes also comprise a temperature sensor for detecting the temperature of the external environment and a humidity sensor for detecting the internal humidity; the air conditioning clothes also comprise a solution humidifying device for adjusting the humidity inside the air conditioning clothes;

the air-conditioning coat further comprises a controller, wherein the controller is preset with temperature interval rules which are sequentially increased by at least six interval thresholds and used for corresponding user feelings including at least cold, low cold, moderate, high heat, hot and extremely hot; at least four interval thresholds which are sequentially increased and used for representing humidity interval rules at least comprising dry, moderate, low-humidity and high-humidity user feelings are preset;

the controller is configured to:

acquiring the external environment temperature and the internal humidity of the air conditioning clothes under the refrigeration working condition;

determining whether a preset regulation condition is satisfied based on the external ambient temperature and the internal humidity; the preset regulation and control conditions comprise that the external environment temperature is in a preset temperature interval for representing that a user feels extremely hot, and the internal humidity is in a preset humidity interval for representing that the user feels moderate;

responding to the external environment temperature and the internal humidity to determine that preset regulation and control conditions are met, and adjusting the running state of the air-conditioning clothes according to preset regulation and control rules corresponding to the preset regulation and control conditions; the regulation and control rule comprises the steps that the solution humidity control device is controlled to operate at the lowest working voltage of a dehumidification mode, the compressor and the circulating water pump operate according to set parameters, the first outer fan operates at a high wind gear, and the second outer fan operates at a high wind gear.

7. The air conditioning garment of claim 6, wherein the controller is further configured to:

acquiring the current working voltage in a control circuit of the air-conditioning clothes;

and when the current working voltage does not meet the preset voltage condition, controlling the power supply mode of the air conditioner clothes battery to be switched to the standby power supply mode.

8. The air conditioning clothes of claim 7, further comprising a power supply, wherein the power supply comprises a solar power panel and a lithium battery, and the solar power panel is connected with the lithium battery through a first output line for charging the lithium battery; the solar power generation panel is connected with the air conditioning module through a second output line and used for supplying power to the air conditioning module; a first switch is arranged on a circuit for connecting the lithium battery and the solar power generation panel, a second switch is arranged on a circuit for connecting the lithium battery and the air conditioning module, and a third switch is arranged on a circuit for connecting the solar power generation panel and the air conditioning module; the first switch, the second switch and the third switch are respectively used for controlling the on-off of the circuit;

the controller is specifically configured to: and controlling the first switch and the second switch to be closed and controlling the second switch to be opened.

9. The air conditioning garment of claim 6, wherein the setting parameter of the compressor comprises a setting frequency, and the controller calculates the setting frequency according to the following formula:

f＝F*K1，

wherein F is the set frequency, and F is the rated working frequency of the compressor; k1 is a frequency scaling factor associated with the regulation condition, and its value is 0.7.

10. The air-conditioning garment as recited in claim 6 or 9, wherein the set parameter of the water circulation pump comprises a set flow rate, and the set flow rate is a maximum flow rate value of the water circulation pump.

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