CN112757873A - Energy-saving logic design method of electric air conditioner - Google Patents

Abstract

The invention discloses an energy-saving logic design method of an electric air conditioner, which comprises the steps of designing the division logic of the use seasons of the electric air conditioner, defining the temperature of the seasons, defining the rotating speed of a compressor in spring and autumn, defining the logic of an air outlet switch point of the electric air conditioner in early summer, defining the logic of the air outlet switch point of the electric air conditioner in summer, defining the rotating speed of the compressor in early summer and summer, defining the updating logic of the rotating speed and defining the rotating speed increasing logic of the compressor in early summer and summer; the season is judged according to the external temperature, the optimal rotating speed of the compressor is judged according to the season, the set temperature, the evaporator temperature and the wind speed gear, the energy-saving logic of the designed electric air conditioner can reduce the energy consumption of the compressor through reducing the rotating speed of the compressor in spring and autumn, the driving endurance mileage of a vehicle can be improved on the premise of meeting the requirement of human body comfort, and the energy-saving effect is good.

Description

Energy-saving logic design method of electric air conditioner

Technical Field

The invention relates to the technical field of energy-saving control of an electric vehicle air conditioner, in particular to an energy-saving logic design method of an electric air conditioner.

Background

At present, for an electric automobile, the endurance of a battery is a matter of most concern of consumers, and the electric energy of the battery is consumed synchronously when an air conditioner is started, so that the endurance of the electric automobile is reduced, and how to realize the effect of meeting the requirement of human body comfort and saving the electric energy under different environments has very important research significance; therefore, the invention provides an energy-saving logic design method of an electric air conditioner, which aims to overcome the defects in the prior art.

Disclosure of Invention

In view of the above problems, an object of the present invention is to provide a method for designing an energy-saving logic of an electric air conditioner, wherein the season is determined according to an external temperature, and the optimal rotation speed of a compressor is determined according to the season, a set temperature, an evaporator temperature and a wind speed gear.

In order to achieve the purpose of the invention, the invention is realized by the following technical scheme:

an energy-saving logic design method of an electric air conditioner comprises the following steps:

the method comprises the following steps: logic for dividing designed electric air conditioner into seasons

Dividing the whole year into four components including spring and autumn, early summer, summer and winter;

step two: defining seasonal temperature

Defining an environmental temperature interval of spring and autumn as 10-18 ℃, defining an environmental temperature interval of early summer as 10-25 ℃, defining an environmental temperature of summer as 25 ℃ and above, and defining an environmental temperature of winter as 10 ℃ and below;

step three: defining the rotation speed of compressor in spring and autumn

When the wind speed is 1 gear, 2 gears and 3 gears, defining the rotating speed of the electric air-conditioning compressor in spring and autumn, and when the wind speed is more than 3 gears, adding an evaporation parameter to define the rotating speed of the electric air-conditioning compressor in spring and autumn;

step four: logic for defining switch point of air outlet of electric air conditioner in early summer

Firstly, defining the temperature compensation standard of the electric air conditioner in early summer as 2 ℃, and then adjusting the switch point logic of the air outlet of the electric air conditioner in early summer according to the temperature compensation standard;

step five: defining summer electric air conditioner air outlet switch point logic

Firstly, defining the temperature compensation standard in summer as 2 ℃, and then adjusting the logic of the switch point of the air outlet of the electric air conditioner in summer according to the temperature compensation standard;

step six: defining compressor speed for early summer and summer

The rotating speed of the electric air-conditioning compressor in the early summer is defined as 2200r/min, and the rotating speed of the electric air-conditioning compressor in the summer is defined as 2500 r/min;

step seven: defining rotational speed update logic

In the rotating speed adjusting process, when the rotating speed is increased, the rotating speed is updated and adjusted every 25 s; when the rotating speed is reduced, updating and adjusting the rotating speed every 5 s;

step eight: defining compressor speed increase logic for early summer and summer

The increase in compressor speed in the early summer and summer is defined when the outlet air temperature is higher than the switch point temperature, when the outlet air temperature is lower than the switch point temperature, and when the outlet air temperature is between the switch point and the switch point.

The further improvement lies in that: in the third step, when the wind speed is 1 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1000r/min, when the wind speed is 2 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1200r/min, and when the wind speed is 3 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1400 r/min.

The further improvement lies in that: in the third step, when the wind speed is higher than 3 grades, the evaporation capacity is larger than 16mm, and the rotating speed of the electric air conditioner compressor in spring and autumn is defined to be 4000 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 12mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined as 3200 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 8mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 2500 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 5mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1700 r/min; when the wind speed is higher than 3 grades, the evaporation capacity is larger than 3mm, and the rotating speed of the electric air-conditioning compressor in spring and autumn is 1300 r/min.

The further improvement lies in that: in the fourth step, when the temperature compensation standard in early summer is 2 ℃, the logic of the switch point of the air outlet of the electric air conditioner in early summer is as follows:

{13,11},//set<22，

{15,13},//set>=22&&set<24，

{17,15},//set>=24&&set<26，

{25,23},//set>26。

the further improvement lies in that: in the fifth step, when the temperature compensation standard in summer is 2 ℃, the summer electric air-conditioning air outlet switching point logic is as follows:

{11,9},//set<22，

{13,11},//set>=22&&set<24，

{15,13},//set>=24&&set<26，

{18,16},//set>26。

the further improvement lies in that: in the step eight, when the outlet air temperature is higher than the temperature of the switch point, the rotating speed of the electric air-conditioning compressor in early summer is increased by 500r/min in a stepping mode, the rotating speed of the electric air-conditioning compressor in summer is increased by 200r/min in a stepping mode, and the maximum critical point of the rotating speed of the electric air-conditioning compressor is 6000 r/min.

The further improvement lies in that: in the step eight, when the outlet air temperature is lower than the temperature of the switch point, the rotating speed of the electric air-conditioning compressor in early summer is reduced by 300r/min in a stepping mode, the rotating speed of the electric air-conditioning compressor in summer is reduced by 100r/min in a stepping mode, and the minimum critical point of the rotating speed of the electric air-conditioning compressor is 1200 r/min.

The further improvement lies in that: in the step eight, when the air outlet temperature is between the opening point and the closing point, the rotating speed of the electric air-conditioning compressor is increased by 500r/min, and the maximum critical point of the rotating speed of the electric air-conditioning compressor is 6000 r/min.

The invention has the beneficial effects that: the energy-saving logic design method of the electric air conditioner judges the season according to the external temperature, and then judges the optimal rotating speed of the compressor according to the season, the set temperature, the evaporator temperature and the wind speed gear, and the designed energy-saving logic of the electric air conditioner can reduce the energy consumption of the compressor by reducing the rotating speed of the compressor in spring and autumn, can improve the driving endurance mileage of a vehicle on the premise of meeting the requirement of human body comfort, and has good energy-saving effect.

Drawings

FIG. 1 is a schematic flow chart of the design method of the present invention.

Detailed Description

In order to further understand the present invention, the following detailed description will be made with reference to the following examples, which are only used for explaining the present invention and are not to be construed as limiting the scope of the present invention.

According to fig. 1, the present embodiment provides a method for designing an energy saving logic of an electric air conditioner, including the following steps:

the method comprises the following steps: logic for dividing designed electric air conditioner into seasons

Dividing the whole year into four components including spring and autumn, early summer, summer and winter;

step two: defining seasonal temperature

Defining an environmental temperature interval of spring and autumn as 10-18 ℃, defining an environmental temperature interval of early summer as 10-25 ℃, defining an environmental temperature of summer as 25 ℃ and above, and defining an environmental temperature of winter as 10 ℃ and below;

step three: defining the rotation speed of compressor in spring and autumn

When the wind speed is 1 gear, 2 gears and 3 gears, defining the rotating speed of the electric air-conditioning compressor in spring and autumn, and when the wind speed is more than 3 gears, adding an evaporation parameter to define the rotating speed of the electric air-conditioning compressor in spring and autumn;

when the wind speed is 1 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1000r/min, when the wind speed is 2 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1200r/min, and when the wind speed is 3 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1400 r/min;

when the wind speed is higher than 3 grades and the evaporation capacity is larger than 16mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 4000 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 12mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined as 3200 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 8mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 2500 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 5mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1700 r/min; when the wind speed is higher than 3 grades, the evaporation capacity is larger than 3mm, and the rotating speed of the electric air-conditioning compressor in spring and autumn is 1300 r/min.

Step four: logic for defining switch point of air outlet of electric air conditioner in early summer

Firstly, defining the temperature compensation standard of the early summer as 2 ℃, and then adjusting the switch point logic of the electric air-conditioning outlet in the early summer according to the temperature compensation standard, wherein the switch point logic of the electric air-conditioning outlet in the early summer is as follows:

{13,11},//set<22，

{15,13},//set>=22&&set<24，

{17,15},//set>=24&&set<26，

{25,23},//set>26；

step five: defining summer electric air conditioner air outlet switch point logic

Firstly, defining the temperature compensation standard in summer as 2 ℃, and then adjusting the switching point logic of the summer electric air-conditioning air outlet according to the temperature compensation standard, wherein the switching point logic of the summer electric air-conditioning air outlet is as follows:

{11,9},//set<22，

{13,11},//set>=22&&set<24，

{15,13},//set>=24&&set<26，

{18,16},//set>26；

step six: defining compressor speed for early summer and summer

The rotating speed of the electric air-conditioning compressor in the early summer is defined as 2200r/min, and the rotating speed of the electric air-conditioning compressor in the summer is defined as 2500 r/min;

step seven: defining rotational speed update logic

In the rotating speed adjusting process, when the rotating speed is increased, the rotating speed is updated and adjusted every 25 s; when the rotating speed is reduced, updating and adjusting the rotating speed every 5 s;

step eight: defining compressor speed increase logic for early summer and summer

Defining the increment of the rotating speed of the compressor in the early summer and the summer when the outlet air temperature is higher than the temperature of the switch point, when the outlet air temperature is lower than the temperature of the switch point and when the outlet air temperature is between the switch point and the switch point;

when the air outlet temperature is higher than the temperature of the switch point, the rotating speed of the electric air-conditioning compressor in early summer is increased by 500r/min in a stepping mode, the rotating speed of the electric air-conditioning compressor in summer is increased by 200r/min in a stepping mode, and the maximum critical point of the rotating speed of the electric air-conditioning compressor is 6000 r/min;

when the air outlet temperature is lower than the temperature of the switch point, the rotating speed of the electric air-conditioning compressor in early summer is reduced by 300r/min in a stepping mode, the rotating speed of the electric air-conditioning compressor in summer is reduced by 100r/min in a stepping mode, and the minimum critical point of the rotating speed of the electric air-conditioning compressor is 1200 r/min;

when the air outlet temperature is between the opening point and the closing point, the rotating speed of the electric air-conditioning compressor is increased by 500r/min, and the maximum critical point of the rotating speed of the electric air-conditioning compressor is 6000 r/min.

The energy-saving logic design method of the electric air conditioner judges the season according to the external temperature, and then judges the optimal rotating speed of the compressor according to the season, the set temperature, the evaporator temperature and the wind speed gear, and the designed energy-saving logic of the electric air conditioner can reduce the energy consumption of the compressor by reducing the rotating speed of the compressor in spring and autumn, can improve the driving endurance mileage of a vehicle on the premise of meeting the requirement of human body comfort, and has good energy-saving effect.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. An energy-saving logic design method of an electric air conditioner is characterized in that: the method comprises the following steps:

the method comprises the following steps: logic for dividing designed electric air conditioner into seasons

Dividing the whole year into four components including spring and autumn, early summer, summer and winter;

step two: defining seasonal temperature

Defining an environmental temperature interval of spring and autumn as 10-18 ℃, defining an environmental temperature interval of early summer as 10-25 ℃, defining an environmental temperature of summer as 25 ℃ and above, and defining an environmental temperature of winter as 10 ℃ and below;

step three: defining the rotation speed of compressor in spring and autumn

When the wind speed is 1 gear, 2 gears and 3 gears, defining the rotating speed of the electric air-conditioning compressor in spring and autumn, and when the wind speed is more than 3 gears, adding an evaporation parameter to define the rotating speed of the electric air-conditioning compressor in spring and autumn;

step four: logic for defining switch point of air outlet of electric air conditioner in early summer

Firstly, defining the temperature compensation standard of the electric air conditioner in early summer as 2 ℃, and then adjusting the switch point logic of the air outlet of the electric air conditioner in early summer according to the temperature compensation standard;

step five: defining summer electric air conditioner air outlet switch point logic

Firstly, defining the temperature compensation standard in summer as 2 ℃, and then adjusting the logic of the switch point of the air outlet of the electric air conditioner in summer according to the temperature compensation standard;

step six: defining compressor speed for early summer and summer

The rotating speed of the electric air-conditioning compressor in the early summer is defined as 2200r/min, and the rotating speed of the electric air-conditioning compressor in the summer is defined as 2500 r/min;

step seven: defining rotational speed update logic

In the rotating speed adjusting process, when the rotating speed is increased, the rotating speed is updated and adjusted every 25 s; when the rotating speed is reduced, updating and adjusting the rotating speed every 5 s;

step eight: defining compressor speed increase logic for early summer and summer

The increase in compressor speed in the early summer and summer is defined when the outlet air temperature is higher than the switch point temperature, when the outlet air temperature is lower than the switch point temperature, and when the outlet air temperature is between the switch point and the switch point.

2. The energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the third step, when the wind speed is 1 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1000r/min, when the wind speed is 2 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1200r/min, and when the wind speed is 3 grade, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1400 r/min.

3. The energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the third step, when the wind speed is higher than 3 grades, the evaporation capacity is larger than 16mm, and the rotating speed of the electric air conditioner compressor in spring and autumn is defined to be 4000 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 12mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined as 3200 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 8mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 2500 r/min; when the wind speed is higher than 3 grades and the evaporation capacity is larger than 5mm, the rotating speed of the electric air-conditioning compressor in spring and autumn is defined to be 1700 r/min; when the wind speed is higher than 3 grades, the evaporation capacity is larger than 3mm, and the rotating speed of the electric air-conditioning compressor in spring and autumn is 1300 r/min.

4. The energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the fourth step, when the temperature compensation standard in early summer is 2 ℃, the logic of the switch point of the air outlet of the electric air conditioner in early summer is as follows:

{13,11},//set<22，

{15,13},//set>=22&&set<24，

{17,15},//set>=24&&set<26，

{25,23},//set>26。

5. the energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the fifth step, when the temperature compensation standard in summer is 2 ℃, the summer electric air-conditioning air outlet switching point logic is as follows:

{11,9},//set<22，

{13,11},//set>=22&&set<24，

{15,13},//set>=24&&set<26，

{18,16},//set>26。

6. the energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the step eight, when the outlet air temperature is higher than the temperature of the switch point, the rotating speed of the electric air-conditioning compressor in early summer is increased by 500r/min in a stepping mode, the rotating speed of the electric air-conditioning compressor in summer is increased by 200r/min in a stepping mode, and the maximum critical point of the rotating speed of the electric air-conditioning compressor is 6000 r/min.

7. The energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the step eight, when the outlet air temperature is lower than the temperature of the switch point, the rotating speed of the electric air-conditioning compressor in early summer is reduced by 300r/min in a stepping mode, the rotating speed of the electric air-conditioning compressor in summer is reduced by 100r/min in a stepping mode, and the minimum critical point of the rotating speed of the electric air-conditioning compressor is 1200 r/min.

8. The energy-saving logic design method of the electric air conditioner as claimed in claim 1, wherein: in the step eight, when the air outlet temperature is between the opening point and the closing point, the rotating speed of the electric air-conditioning compressor is increased by 500r/min, and the maximum critical point of the rotating speed of the electric air-conditioning compressor is 6000 r/min.

Images