CN104613598A - Energy-saving monitoring method and device used for air-conditioner - Google Patents

Abstract

The invention discloses an energy-saving monitoring method and device used for an air-conditioner. A unit of the air-conditioner comprises four air processing sections including the preheating section, the cooling section, the heating section and the humidifying section. A specific execution mode of the energy-saving monitoring method includes the steps of obtaining temperature-humidity parameters of air in a preset area of the air-conditioner; based on the temperature-humidity parameters, determining the current working conditions of the air-conditioner by comparing the temperature and the humidity of fed air with the temperature and the humidity of returned air; based on the current working condition of the air-conditioner, determining whether the air-conditioner has unreasonable running phenomena or not by analyzing the temperature-humidity parameters of the air in the preset area. By means of the execution mode, energy-saving running of the air-conditioner is achieved, and energy waste is reduced.

Description

For energy-saving monitoring method and the device of air-conditioning

Technical field

The application relates to air-conditioner technical field, is specifically related to technical field of air conditioner, particularly relates to a kind of energy-saving monitoring method for air-conditioning and device.

Background technology

Air-conditioning is as a kind of conventional basic operational outfit, very general in modern architecture.But often there is a lot of irrational phenomenon in air-conditioning in the middle of the operation of reality.Especially constant-temperature constant-humidity air-conditioner.

Constant-temperature constant-humidity air-conditioner refers to special air conditioner temperature, humidity and cleanliness factor being had to strict control overflow, is widely used in the industries such as electronics, optical device, cosmetics, health care, bio-pharmaceuticals, food manufacturing, all kinds of gauge check and laboratory.

Because constant-temperature constant-humidity air-conditioner control accuracy is high, air handling process is complicated, the reason such as robot control system(RCS) modulability and poor stability makes the controlling run of constant-temperature constant-humidity air-conditioner often there are problems, and the most outstanding with cold-hot counteraction problem.These all cause the operation energy consumption of constant-temperature constant-humidity air-conditioner higher, and the energy saving space is larger.

Summary of the invention

This application provides a kind of energy-saving monitoring method for air-conditioning and device.

On the one hand, this application provides a kind of energy-saving monitoring method for air-conditioning, preheating section is comprised in the unit of described air-conditioning, cooling section, bringing-up section, humidifier section four air-treatment sections, it is characterized in that, described method comprises: the humiture parameter obtaining air in described air-conditioning presumptive area, described humiture parameter comprises: new air temperature T1, new rheumatism degree D1, return air temperature T2, return air humidity D2, air themperature T3 before described cooling section, air humidity D3 before described cooling section, air themperature T4 after described cooling section, air humidity D4 after described cooling section, air themperature T5 before described humidifier section, air humidity D5 before described humidifier section, and wind pushing temperature T6, blasting humidity D6, based on described humiture parameter, by the humiture of the humiture and return air that compare air-supply, determine the working condition that described air-conditioning is current, and based on the current working condition of described air-conditioning, determine whether described air-conditioning exists irrational operation phenomenon by the humiture parameter analyzing air in described presumptive area.

In some embodiments, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: determine the current residing external ambient conditions of described air-conditioning; Based on described external ambient conditions, determine whether described air-conditioning exists irrational operation phenomenon by the humiture parameter analyzing air in described presumptive area.

In some embodiments, describedly determine that the current external ambient conditions of described air-conditioning comprises: determine that whether described new air temperature T1 is lower than preset temperature threshold value; If so, then determine that the current external ambient conditions of described air-conditioning is winter environment.If not, then determine that the current external ambient conditions of described air-conditioning is non-winter environment.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 is greater than described return air temperature T2, and described blasting humidity D6 is greater than described return air humidity D2, then determine that the current working condition of described air-conditioning is warming and humidifying working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, air themperature T3 before the described cooling section air themperature T4 be greater than after described wind pushing temperature T6 and/or described cooling section is less than the air themperature T3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, the air themperature T3 before described cooling section is less than the air themperature T4 after described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 is less than described return air temperature T2, and described blasting humidity D6 is greater than described return air humidity D2, then determine that the current working condition of described air-conditioning is decreasing temperature and increasing humidity working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, air themperature T5 before described humidifier section is greater than the air themperature T4 after described cooling section and the air themperature T4 after described cooling section is less than the air themperature T3 before described cooling section and/or the air themperature T3 before described cooling section is greater than described return air temperature T2, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, air themperature T5 before described humidifier section is greater than the air themperature T4 after described cooling section and the air themperature T4 after described cooling section is less than air themperature T3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 is less than described return air temperature T2, and described blasting humidity D6 is less than described return air humidity D2, then determine that the current working condition of described air-conditioning is reducing temperature and humidity working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and/or the air themperature T3 before described cooling section is greater than described return air temperature T2, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 is greater than described return air temperature T2, and described blasting humidity D6 is less than described return air humidity D2, then determine that the current working condition of described air-conditioning is for heating wet down working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 is less than described return air temperature T2, and described blasting humidity D6 equals described return air humidity D2, then determine that the current working condition of described air-conditioning such as is at the wet cooling working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air themperature T5 be less than before described return air humidity D2 and/or described humidifier section of the air humidity D3 before described cooling section is greater than the air themperature T4 after described cooling section and the air themperature T3 be less than before described return air humidity D2 and/or described cooling section of the air humidity D3 before described cooling section is greater than described return air temperature T2, then determine that described air-conditioning exists irrational operation phenomenon, if and the current external ambient conditions of described air-conditioning is described non-winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air themperature T5 be less than before described return air humidity D2 and/or described humidifier section of the air humidity D3 before described cooling section is greater than the air themperature T4 after described cooling section and the air humidity D3 before described cooling section is less than described return air humidity D2, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 is greater than described return air temperature T2, and described blasting humidity D6 equals described return air humidity D2, then determine that the current working condition of described air-conditioning is etc. wetly heat working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air humidity D3 before described cooling section is less than described return air humidity D2 and/or described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D3 before described cooling section is greater than described return air humidity D2, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air humidity D3 before described cooling section is less than described return air humidity D2 and/or described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D3 before described cooling section is greater than described return air humidity D2, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 equals described return air temperature T2, and described blasting humidity D6 is less than described return air humidity D2, then determine that the current working condition of described air-conditioning is isothermal wet down working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, air themperature T3 before described cooling section is greater than described return air temperature T2 and/or described blasting humidity D6 and is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises: if described wind pushing temperature T6 equals described return air temperature T2, and described blasting humidity D6 is greater than described return air humidity D2, then determine that the current working condition of described air-conditioning is isothermal humidification working condition.

Further, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise: if the current external ambient conditions of described air-conditioning is described winter environment, air themperature T3 before the described cooling section air themperature T4 be greater than after described return air temperature T2 and/or described cooling section is less than the air themperature T3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And if the current external ambient conditions of described air-conditioning is described non-winter environment, air humidity D4 after described cooling section is less than air humidity D3 before described cooling section and described blasting humidity D6 is greater than air humidity D4 after described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

In some embodiments, described method also comprises: if described air-conditioning exists irrational operation phenomenon, then present information, wherein, described information comprises: described irrational operation phenomenon and/or the operation suggestion built according to described irrational operation phenomenon.

In some embodiments, described operation suggestion comprises following at least one item: Open valve, valve-off, increase valve opening, the valve opening that reduces, opening device, closing device, increase opening of device number of units, the opening of device number of units that reduces, increase are opened dutycycle, reduced to open dutycycle.

Second aspect, this application provides a kind of energy-saving monitoring apparatus for air-conditioning, preheating section is comprised in the unit of described air-conditioning, cooling section, bringing-up section, humidifier section four air-treatment sections, it is characterized in that, described device comprises: parameter acquiring unit, for obtaining the humiture parameter of air in described air-conditioning presumptive area, described humiture parameter comprises: new air temperature T1, new rheumatism degree D1, return air temperature T2, return air humidity D2, air themperature T3 before described cooling section, air humidity D3 before described cooling section, air themperature T4 after described cooling section, air humidity D4 after described cooling section, air themperature T5 before described humidifier section, air humidity D5 before described humidifier section, and wind pushing temperature T6, blasting humidity D6, working condition determining unit, for based on described humiture parameter, by the humiture of the humiture and return air that compare air-supply, determines the working condition that described air-conditioning is current, and run phenomenon determining unit, for based on the current working condition of described air-conditioning, determine whether described air-conditioning exists irrational operation phenomenon by the humiture parameter analyzing air in described presumptive area.

In some embodiments, described operation phenomenon determining unit comprises: external environment condition determination subelement, for determining the current residing external ambient conditions of described air-conditioning; And data analysis subelement, for based on described external ambient conditions, analyze the humiture parameter of air in described presumptive area to determine whether described air-conditioning exists irrational operation phenomenon.

The energy-saving monitoring method for air-conditioning that the application provides and device, can be applicable in constant-temperature constant-humidity air-conditioner, preheating section is comprised in the unit of wherein this air-conditioning, cooling section, bringing-up section, humidifier section four air-treatment sections, first the humiture parameter of air in this air-conditioning presumptive area is obtained, then based on this humiture parameter, by the humiture of the humiture and return air that compare air-supply, determine the working condition that air-conditioning is current, afterwards based on the working condition that this air-conditioning is current, irrational operation phenomenon whether is there is by the humiture parameter determination air-conditioning analyzing air in presumptive area, achieve energy-saving operation of air conditioner, reduce energy waste.

Accompanying drawing explanation

By reading the detailed description done non-limiting example done with reference to the following drawings, the other features, objects and advantages of the application will become more obvious:

Fig. 1 shows the exemplary block diagram of the energy-saving monitoring system for air-conditioning that the application provides;

Fig. 2 shows air-treatment segment structure and aerial temperature and humidity collection point schematic diagram in thermostatic and humidistatic air conditioning unit group;

Fig. 3 shows the flow chart of an embodiment of the energy-saving monitoring method for air-conditioning that the application provides.

Detailed description of the invention

Below in conjunction with drawings and Examples, the application is described in further detail.Be understandable that, specific embodiment described herein is only for explaining related invention, but not the restriction to this invention.It also should be noted that, for convenience of description, in accompanying drawing, illustrate only the part relevant to Invention.

It should be noted that, when not conflicting, the embodiment in the application and the feature in embodiment can combine mutually.Below with reference to the accompanying drawings and describe the application in detail in conjunction with the embodiments.

Please refer to Fig. 1, it illustrates the exemplary block diagram of the energy-saving monitoring system for air-conditioning that the application provides.

As shown in Figure 1, this energy-saving monitoring system 100 mainly comprises parameter acquiring unit 110, runs phenomenon determining unit 120.

Parameter acquiring unit 110 can comprise multiple sensors, for obtaining dissimilar environmental information.Generally speaking, parameter acquiring unit 110 comprises temperature sensor 111 and humidity sensor 112.

Temperature sensor refers to can experience temperature and the sensor converting usable output signal to.In the present embodiment, temperature sensor 111 can be configured for the temperature information obtaining difference in functionality section air in air-conditioner set.

Humidity sensor refers to that humidity amount can be converted to can the equipment of the signal of telecommunication of measured process or device.In the present embodiment, humidity sensor 112 can be configured for the humidity information obtaining difference in functionality section air in air-conditioner set.

Fig. 2 shows air-treatment segment structure and aerial temperature and humidity collection point schematic diagram in thermostatic and humidistatic air conditioning unit group.

As shown in Figure 2, in general, the functional section in thermostatic and humidistatic air conditioning unit group mainly comprises new wind section 201, air return section 202, preheating section 203, cooling section 204, bringing-up section 205, humidifier section 206 and air supply section 207.Wherein, preheating section 203, cooling section 204, bringing-up section 205, humidifier section 206 are four air-treatment sections, are used for processing the air entering air-conditioning according to the operation conditions of air-conditioning.

New wind section 201 is used for gathering new wind, such as, can be the fresh air without air-conditioning process, can comprise outdoor air, to reach the object of indoor-outdoor air circulation.New wind section 201 can connect new wind airduct, and fresh inlet has jacking wind and side air intake two kinds of forms, can be furnished with leafy volume damper, for regulating new wind air force.Air return section 202 may be used for taking back airduct, for providing the air inlet of return air, such as, after the air of air-conditioning process mixes with room air, again enters air-conditioning repeatedly process.At the top of air return section 202 or sidepiece, leafy volume damper can be housed, for regulating return air air force.

Preheating section 203, cooling section 204, bringing-up section 205, humidifier section 206 are four air-treatment sections, process accordingly respectively to the new wind or return air that enter air-conditioning.Preheating section 203 and bringing-up section 205 such as can adopt Steam Heating, hot water heating and electrical heating three kinds of mode of heatings.Cooling section 204 can be used for carrying out cool-down dehumidification process to air, when air humidity requires high than indoor, can be reached the object of cool-down dehumidification by coil pipe refrigeration.Humidifier section 206 is commonly used the humidifiers such as dry type seam humidifier, high-pressure atomizing humidifier and is added wet process to air.

After air supply section 207 is located at humidifier section 206, is used for adjusting air-supply Way out, and is connected with supply air duct, interface can be installed air-valve and carry out adjustment air-supply air force.

In the present embodiment, temperature sensor 111 and humidity sensor 112 can configure the humiture information for obtaining difference in functionality section air in air-conditioner set.Such as, this humiture information can include but not limited to: new air temperature T1, new rheumatism degree D1, return air temperature T2, return air humidity D2, the air themperature T3 before cooling section, the air humidity D3 before cooling section, air themperature T4 after cooling section, air humidity D4 after cooling section, the air themperature T5 before humidifier section, the air humidity D5 before humidifier section, and wind pushing temperature T6, blasting humidity D6.

In some optional implementations, the Temperature Humidity Sensor (not shown) that simultaneously can obtain temperature information and humidity information in environment can also be adopted to obtain the humiture information of difference in functionality section air in air-conditioner set.

Whether the operation phenomenon determining unit 120 in energy-saving monitoring system 100 exists irrational operation phenomenon for the humiture parameter determination air-conditioning by analyzing difference in functionality section air in air-conditioner set.Run phenomenon determining unit 120 and such as can comprise external environment condition determination subelement 121 and data analysis subelement 122.

External environment condition determination subelement 121 can be configured for determines the current residing external ambient conditions of air-conditioning.Such as, the humiture parameter that external environment condition determination subelement 121 can obtain based on parameter acquiring unit 110, by judging whether new air temperature T1 determines the current residing external ambient conditions of air-conditioning lower than preset temperature threshold value, such as, preset temperature threshold value is 10 DEG C, when new air temperature T1 is lower than 10 DEG C, judge that the current external ambient conditions of air-conditioning is as winter environment; When new air temperature T1 is equal to or higher than 10 DEG C, judge that the current external ambient conditions of air-conditioning is as non-winter environment.

Data analysis subelement 122 can be configured for based on external ambient conditions, by analyzing the humiture parameter of difference in functionality section air in air-conditioner set to determine whether air-conditioning exists irrational operation phenomenon.

In the present embodiment, energy-saving monitoring system 100 parameter acquiring unit 110 and run and can directly connect with transmission information between phenomenon determining unit 120.Such as, parameter acquiring unit 110 can by the aerial temperature and humidity parameter transmission of the air-conditioning difference in functionality section obtained to running phenomenon determining unit 120.

In the optional implementation of the one of the present embodiment, energy-saving monitoring system can comprise network communication unit 140, and it can be connected to such as internet 130, with from network acquisition information.Such as, parameter acquiring unit 110 can by the aerial temperature and humidity parameter transmission of the air-conditioning difference in functionality section of acquisition to internet 130, and network communication unit 140 receives humiture parameter from internet 130, and then is transferred to operation phenomenon determining unit 120.

Below in conjunction with flow chart, the energy-saving monitoring method for air-conditioning that the application provides is described.

Fig. 3 shows the flow chart of an embodiment of the energy-saving monitoring method for air-conditioning that the application provides.

As shown in Figure 3, in step 301, the humiture parameter of air in air-conditioning presumptive area is obtained.

Functional section in thermostatic and humidistatic air conditioning unit group mainly comprises new wind section 201, air return section 202, preheating section 203, cooling section 204, bringing-up section 205, humidifier section 206 and air supply section 207 as shown in Figure 2.In the present embodiment, the temperature sensor 111 shown in Fig. 1 and humidity sensor 112 can be used to obtain the humiture information of difference in functionality section air in air-conditioner set.Such as, this humiture information can include but not limited to: new air temperature T1, new rheumatism degree D1, return air temperature T2, return air humidity D2, the air themperature T3 before cooling section, the air humidity D3 before cooling section, air themperature T4 after cooling section, air humidity D4 after cooling section, the air themperature T5 before humidifier section, the air humidity D5 before humidifier section, and wind pushing temperature T6, blasting humidity D6.

Then, in step 302, based on humiture parameter, by the humiture of the humiture and return air that compare air-supply, the working condition that air-conditioning is current is determined.

In the present embodiment, based on the humiture parameter of the air-conditioning difference in functionality section air obtained in step 301, determine by comparing wind pushing temperature T6 and return air temperature T2, blasting humidity D6 and return air humidity D2 the working condition that air-conditioning is current.

In the optional implementation of the one of the present embodiment, if wind pushing temperature T6 is greater than return air temperature T2, and blasting humidity D6 is greater than return air humidity D2, then determine that the current working condition of air-conditioning is warming and humidifying working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 is less than return air temperature T2, and blasting humidity D6 is greater than return air humidity D2, then determine that the current working condition of air-conditioning is decreasing temperature and increasing humidity working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 is less than return air temperature T2, and blasting humidity D6 is less than return air humidity D2, then determine that the current working condition of air-conditioning is reducing temperature and humidity working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 is greater than return air temperature T2, and blasting humidity D6 is less than return air humidity D2, then determine that the current working condition of air-conditioning is for heating wet down working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 is less than return air temperature T2, and blasting humidity D6 equals return air humidity D2, then determine that the current working condition of air-conditioning such as is at the wet cooling working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 is greater than return air temperature T2, and blasting humidity D6 equals return air humidity D2, then determine that the current working condition of air-conditioning is etc. wetly heat working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 equals return air temperature T2, and blasting humidity D6 is less than return air humidity D2, then determine that the current working condition of air-conditioning is isothermal wet down working condition.

In the optional implementation of the another kind of the present embodiment, if wind pushing temperature T6 equals return air temperature T2, and blasting humidity D6 is greater than return air humidity D2, then determine that the current working condition of air-conditioning is isothermal humidification working condition.

Finally, in step 303, based on the working condition that air-conditioning is current, whether there is irrational operation phenomenon by the humiture parameter determination air-conditioning analyzing air in presumptive area.

In the present embodiment, based on the working condition that the air-conditioning determined in step 302 is current, under this working condition, the air handling process be not inconsistent with this working condition may be there is in air-conditioner set, i.e. irrational operation phenomenon, by analyzing the humiture parameter of air-conditioning difference in functionality section air, determine whether air-conditioning exists irrational operation phenomenon.

In certain embodiments, also need to judge whether air-conditioning exists irrational operation phenomenon based on external ambient conditions.When external ambient conditions is different, judge whether air-conditioning exists the standard of unreasonable operation phenomenon also not identical.In the present embodiment, can such as, by judging whether new air temperature T1 determines the current residing external ambient conditions of air-conditioning lower than preset temperature threshold value, and, preset temperature threshold value is 10 DEG C, when new air temperature T1 is lower than 10 DEG C, judge that the current external ambient conditions of air-conditioning is as winter environment; When new air temperature T1 is equal to or higher than 10 DEG C, judge that the current external ambient conditions of air-conditioning is as non-winter environment.

Alternatively or additionally, if air-conditioning exists irrational operation phenomenon, then system can present information.The operation suggestion that this information can include but not limited to this irrational operation phenomenon and/or build according to this irrational operation phenomenon.Corresponding to the different structure of air-conditioning, this operation suggestion can comprise following at least one item: Open valve, valve-off, increase valve opening, the valve opening that reduces, opening device, closing device, increase opening of device number of units, the opening of device number of units that reduces, increase are opened dutycycle, reduced to open dutycycle.Such as, when the air-treatment section of air-conditioning is that when regulating air mass flow size by valve, above-mentioned operation suggestion can comprise: Open valve, valve-off, increase valve opening, reduce valve opening etc.When the air-treatment section of air-conditioning is all or part of realized regulating air mass flow size by individual equipment start and stop dutycycle or start and stop number of units (number) time, above-mentioned operation suggestion can comprise: opening device, closing device, increase opening of device number of units, reduce opening of device number of units, increase and open dutycycle, reduce to open dutycycle etc.In the present embodiment with the air-treatment section of air-conditioning be by valve regulate air mass flow size describe in detail above-mentioned operation suggestion.

In the optional implementation of the one of the present embodiment, when air-conditioning is in warming and humidifying working condition, and the current external ambient conditions of air-conditioning is winter environment, if the air themperature T3 before cooling section is greater than wind pushing temperature T6, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing preheating section valve opening; If the air themperature T4 after cooling section be less than cooling section before air themperature T3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing cooling section valve.When air-conditioning is in warming and humidifying working condition, and the current external ambient conditions of air-conditioning is non-winter environment, if the air themperature T3 before cooling section be less than cooling section after air themperature T4, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing cooling section valve.

In the optional implementation of the another kind of the present embodiment, when air-conditioning is in decreasing temperature and increasing humidity working condition, and the current external ambient conditions of air-conditioning is winter environment, if the air themperature T5 before humidifier section be greater than cooling section after air themperature T4 and air themperature T4 after cooling section be less than cooling section before air themperature T3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing bringing-up section valve, reducing cooling section valve opening; If the air themperature T3 before cooling section is greater than return air temperature T2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing preheating section valve opening.When air-conditioning is in decreasing temperature and increasing humidity working condition, and the current external ambient conditions of air-conditioning is non-winter environment, if the air themperature T5 before humidifier section be greater than cooling section after air themperature T4 and air themperature T4 after cooling section be less than cooling section before air themperature T3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing bringing-up section valve, reducing cooling section valve opening.

In the optional implementation of the another kind of the present embodiment, when air-conditioning is in reducing temperature and humidity working condition, and the current external ambient conditions of air-conditioning is winter environment, if blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D4 after cooling section be less than cooling section before air humidity D3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve, reducing cooling section valve opening; If the air themperature T3 before cooling section is greater than return air temperature T2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing preheating section valve opening.When air-conditioning is in reducing temperature and humidity working condition, and the current external ambient conditions of air-conditioning is non-winter environment, if blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D4 after cooling section be less than cooling section before air humidity D3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve, reducing cooling section valve opening.

In the optional implementation of the another kind of the present embodiment, when air-conditioning be in heat wet down working condition time, and the current external ambient conditions of air-conditioning is winter environment, if blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D4 after cooling section be less than cooling section before air humidity D3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve, reducing cooling section valve opening.When air-conditioning be in heat wet down working condition time, and the current external ambient conditions of air-conditioning is non-winter environment, if blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D4 after cooling section be less than cooling section before air humidity D3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve, reducing cooling section valve opening.

In the optional implementation of the another kind of the present embodiment, when wet cooling working conditions such as air-conditioning are in, and the current external ambient conditions of air-conditioning is winter environment, if the air humidity D4 after cooling section be less than cooling section before air humidity D3 and air humidity D3 before cooling section is less than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing cooling section valve opening; If the air themperature T5 before humidifier section be greater than cooling section after air themperature T4 and air humidity D3 before cooling section is less than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing bringing-up section valve, reducing cooling section valve opening; If the air themperature T3 before cooling section is greater than return air temperature T2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing preheating section valve opening.When wet cooling working conditions such as air-conditioning are in, and the current external ambient conditions of air-conditioning is non-winter environment, if the air humidity D4 after cooling section be less than cooling section before air humidity D3 and air humidity D3 before cooling section is less than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing cooling section valve opening; If the air themperature T5 before humidifier section be greater than cooling section after air themperature T4 and air humidity D3 before cooling section is less than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing bringing-up section valve, reducing cooling section valve opening.

In the optional implementation of the another kind of the present embodiment, when air-conditioning to be in etc. wet heat working condition time, and the current external ambient conditions of air-conditioning is winter environment, if the air humidity D4 after cooling section be less than cooling section before air humidity D3 and air humidity D3 before cooling section is less than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing cooling section valve; If blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D3 before cooling section is greater than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve.When air-conditioning to be in etc. wet heat working condition time, and the current external ambient conditions of air-conditioning is non-winter environment, if the air humidity D4 after cooling section be less than cooling section before air humidity D3 and air humidity D3 before cooling section is less than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing cooling section valve; If blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D3 before cooling section is greater than return air humidity D2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve.

In the optional implementation of the another kind of the present embodiment, when air-conditioning is in isothermal wet down working condition, and the current external ambient conditions of air-conditioning is winter environment, if the air themperature T3 before cooling section is greater than return air temperature T2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing preheating section valve opening; If blasting humidity D6 be greater than cooling section after air humidity D4 and air humidity D4 after cooling section be less than cooling section before air humidity D3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section, reducing cooling section valve opening.When air-conditioning is in isothermal wet down working condition, and the current external ambient conditions of air-conditioning is non-winter environment, if blasting humidity D6 be greater than cooling section after air humidity D4, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing humidifier section valve.

In the optional implementation of the another kind of the present embodiment, when air-conditioning is in isothermal humidification working condition, and the current external ambient conditions of air-conditioning is winter environment, if the air themperature T3 before cooling section is greater than return air temperature T2, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing preheating section valve opening; If the air themperature T4 after cooling section be less than cooling section before air themperature T3, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for closing cooling section valve.When air-conditioning is in isothermal humidification working condition, and the current external ambient conditions of air-conditioning is non-winter environment, if the air humidity D4 after cooling section be less than cooling section before air humidity D3 and blasting humidity D6 be greater than cooling section after air humidity D4, then determine that air-conditioning exists irrational operation phenomenon, corresponding operation suggestion is for reducing cooling section valve opening.

The energy-saving monitoring method for air-conditioning that above-described embodiment of the application provides, by obtaining the humiture parameter of air in air-conditioning presumptive area, then based on this humiture parameter, by the humiture of the humiture and return air that compare air-supply, determine the working condition that air-conditioning is current, afterwards based on the working condition that this air-conditioning is current, whether there is irrational operation phenomenon by the humiture parameter determination air-conditioning analyzing air in presumptive area, achieve energy-saving operation of air conditioner, reduce energy waste.

It should be noted that being described in unit module involved in the embodiment of the present application can be realized by the mode of software, also can be realized by the mode of hardware.Described unit module also can be arranged within a processor, such as, can be described as: a kind of processor comprises parameter acquiring unit, working condition determining unit and runs phenomenon determining unit.Wherein, the title of these unit modules does not form the restriction to this unit module itself under certain conditions, and such as, parameter acquiring unit can also be described to " for obtaining the unit of aerial temperature and humidity parameter in presumptive area ".

More than describe and be only the preferred embodiment of the application and the explanation to institute's application technology principle.Those skilled in the art are to be understood that, invention scope involved in the application, be not limited to the technical scheme of the particular combination of above-mentioned technical characteristic, also should be encompassed in when not departing from described inventive concept simultaneously, be undertaken being combined by above-mentioned technical characteristic or its equivalent feature and other technical scheme of being formed.The technical characteristic that such as, disclosed in above-mentioned feature and the application (but being not limited to) has similar functions is replaced mutually and the technical scheme formed.

Claims (23)

1., for an energy-saving monitoring method for air-conditioning, comprise preheating section, cooling section, bringing-up section, humidifier section four air-treatment sections in the unit of described air-conditioning, it is characterized in that, described method comprises:

Obtain the humiture parameter of air in described air-conditioning presumptive area, described humiture parameter comprises: new air temperature T1, new rheumatism degree D1, return air temperature T2, return air humidity D2, the air themperature T3 before described cooling section, the air humidity D3 before described cooling section, air themperature T4 after described cooling section, air humidity D4 after described cooling section, the air themperature T5 before described humidifier section, the air humidity D5 before described humidifier section, and wind pushing temperature T6, blasting humidity D6;

Based on described humiture parameter, by the humiture of the humiture and return air that compare air-supply, determine the working condition that described air-conditioning is current; And

Based on the working condition that described air-conditioning is current, determine whether described air-conditioning exists irrational operation phenomenon by the humiture parameter analyzing air in described presumptive area.

2. energy-saving monitoring method according to claim 1, is characterized in that, describedly determines whether described air-conditioning exists irrational operation phenomenon and comprise:

Determine the current residing external ambient conditions of described air-conditioning;

Based on described external ambient conditions, determine whether described air-conditioning exists irrational operation phenomenon by the humiture parameter analyzing air in described presumptive area.

3. energy-saving monitoring method according to claim 2, is characterized in that, describedly determines that the current external ambient conditions of described air-conditioning comprises:

Determine that whether described new air temperature T1 is lower than preset temperature threshold value;

If so, then determine that the current external ambient conditions of described air-conditioning is winter environment.

If not, then determine that the current external ambient conditions of described air-conditioning is non-winter environment.

4. energy-saving monitoring method according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determines that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 is greater than described return air temperature T2, and described blasting humidity D6 is greater than described return air humidity D2, then determine that the current working condition of described air-conditioning is warming and humidifying working condition.

5. energy-saving monitoring method according to claim 4, is characterized in that, describedly determines whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, air themperature T3 before the described cooling section air themperature T4 be greater than after described wind pushing temperature T6 and/or described cooling section is less than the air themperature T3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, the air themperature T3 before described cooling section is less than the air themperature T4 after described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

6. energy-saving monitoring method according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determines that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 is less than described return air temperature T2, and described blasting humidity D6 is greater than described return air humidity D2, then determine that the current working condition of described air-conditioning is decreasing temperature and increasing humidity working condition.

7. energy-saving monitoring method according to claim 6, is characterized in that, describedly determines whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, air themperature T5 before described humidifier section is greater than the air themperature T4 after described cooling section and the air themperature T4 after described cooling section is less than the air themperature T3 before described cooling section and/or the air themperature T3 before described cooling section is greater than described return air temperature T2, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, air themperature T5 before described humidifier section is greater than the air themperature T4 after described cooling section and the air themperature T4 after described cooling section is less than air themperature T3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

8. energy-saving monitoring method according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determines that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 is less than described return air temperature T2, and described blasting humidity D6 is less than described return air humidity D2, then determine that the current working condition of described air-conditioning is reducing temperature and humidity working condition.

9. energy-saving monitoring method according to claim 8, is characterized in that, describedly determines whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and/or the air themperature T3 before described cooling section is greater than described return air temperature T2, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

10. energy-saving monitoring method according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determines that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 is greater than described return air temperature T2, and described blasting humidity D6 is less than described return air humidity D2, then determine that the current working condition of described air-conditioning is for heating wet down working condition.

11. energy-saving monitoring methods according to claim 10, is characterized in that, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

12. energy-saving monitoring methods according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 is less than described return air temperature T2, and described blasting humidity D6 equals described return air humidity D2, then determine that the current working condition of described air-conditioning such as is at the wet cooling working condition.

13. energy-saving monitoring methods according to claim 12, is characterized in that, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air themperature T5 be less than before described return air humidity D2 and/or described humidifier section of the air humidity D3 before described cooling section is greater than the air themperature T4 after described cooling section and the air themperature T3 be less than before described return air humidity D2 and/or described cooling section of the air humidity D3 before described cooling section is greater than described return air temperature T2, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air themperature T5 be less than before described return air humidity D2 and/or described humidifier section of the air humidity D3 before described cooling section is greater than the air themperature T4 after described cooling section and the air humidity D3 before described cooling section is less than described return air humidity D2, then determine that described air-conditioning exists irrational operation phenomenon.

14. energy-saving monitoring methods according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 is greater than described return air temperature T2, and described blasting humidity D6 equals described return air humidity D2, then determine that the current working condition of described air-conditioning is etc. wetly heat working condition.

15. energy-saving monitoring methods according to claim 14, is characterized in that, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air humidity D3 before described cooling section is less than described return air humidity D2 and/or described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D3 before described cooling section is greater than described return air humidity D2, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, air humidity D4 after described cooling section is less than the air humidity D3 before described cooling section and the air humidity D3 before described cooling section is less than described return air humidity D2 and/or described blasting humidity D6 is greater than the air humidity D4 after described cooling section and the air humidity D3 before described cooling section is greater than described return air humidity D2, then determine that described air-conditioning exists irrational operation phenomenon.

16. energy-saving monitoring methods according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 equals described return air temperature T2, and described blasting humidity D6 is less than described return air humidity D2, then determine that the current working condition of described air-conditioning is isothermal wet down working condition.

17. energy-saving monitoring methods according to claim 16, is characterized in that, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, air themperature T3 before described cooling section is greater than described return air temperature T2 and/or described blasting humidity D6 and is greater than the air humidity D4 after described cooling section and the air humidity D4 after described cooling section is less than air humidity D3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, described blasting humidity D6 is greater than the air humidity D4 after described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

18. energy-saving monitoring methods according to claim 3, is characterized in that, the humiture of described humiture and return air by comparing air-supply, determine that the current working condition of described air-conditioning comprises:

If described wind pushing temperature T6 equals described return air temperature T2, and described blasting humidity D6 is greater than described return air humidity D2, then determine that the current working condition of described air-conditioning is isothermal humidification working condition.

19. energy-saving monitoring methods according to claim 18, is characterized in that, describedly determine whether described air-conditioning exists irrational operation phenomenon and comprise:

If the current external ambient conditions of described air-conditioning is described winter environment, air themperature T3 before the described cooling section air themperature T4 be greater than after described return air temperature T2 and/or described cooling section is less than the air themperature T3 before described cooling section, then determine that described air-conditioning exists irrational operation phenomenon; And

If the current external ambient conditions of described air-conditioning is described non-winter environment, air humidity D4 after described cooling section is less than air humidity D3 before described cooling section and described blasting humidity D6 is greater than air humidity D4 after described cooling section, then determine that described air-conditioning exists irrational operation phenomenon.

20. energy-saving monitoring methods according to any one of claim 1-19, it is characterized in that, described method also comprises:

If described air-conditioning exists irrational operation phenomenon, then present information, wherein, described information comprises: described irrational operation phenomenon and/or the operation suggestion built according to described irrational operation phenomenon.

21. energy-saving monitoring methods according to claim 20, it is characterized in that, described operation suggestion comprises following at least one item: Open valve, valve-off, increase valve opening, the valve opening that reduces, opening device, closing device, increase opening of device number of units, the opening of device number of units that reduces, increase are opened dutycycle, reduced to open dutycycle.

22. 1 kinds of energy-saving monitoring apparatus for air-conditioning, comprise preheating section, cooling section, bringing-up section, humidifier section four air-treatment sections in the unit of described air-conditioning, it is characterized in that, described device comprises:

Parameter acquiring unit, for obtaining the humiture parameter of air in described air-conditioning presumptive area, described humiture parameter comprises: new air temperature T1, new rheumatism degree D1, return air temperature T2, return air humidity D2, air themperature T3 before described cooling section, air humidity D3 before described cooling section, the air themperature T4 after described cooling section, the air humidity D4 after described cooling section, air themperature T5 before described humidifier section, air humidity D5 before described humidifier section, and wind pushing temperature T6, blasting humidity D6;

Working condition determining unit, for based on described humiture parameter, by the humiture of the humiture and return air that compare air-supply, determines the working condition that described air-conditioning is current; And

Run phenomenon determining unit, for based on the current working condition of described air-conditioning, determine whether described air-conditioning exists irrational operation phenomenon by the humiture parameter analyzing air in described presumptive area.

23. energy-saving monitoring apparatus according to claim 22, is characterized in that, described operation phenomenon determining unit comprises:

External environment condition determination subelement, for determining the current residing external ambient conditions of described air-conditioning; And

Data analysis subelement, for based on described external ambient conditions, analyzes the humiture parameter of air in described presumptive area to determine whether described air-conditioning exists irrational operation phenomenon.