CN112880021B - Control device and method of air conditioner and air conditioner - Google Patents

Abstract

The invention discloses a control device and a control method of an air conditioner and the air conditioner, wherein the air conditioner comprises the following components: the first air deflector unit (1) is arranged between a fan (4) and a heat exchanger (8) of the air conditioner, and the current air deflection angle of the first air deflector unit (1) can be adjusted; a control device for an air conditioner, comprising: a detection unit and a control unit; the control unit is configured to control the current air guide angle of the first air deflector unit (1) to be at a set angle under the condition that the air conditioner is started and operated; a detection unit configured to detect a wind speed of a surface of the heat exchanger (8) during operation of the air conditioner; the control unit is configured to adjust the current wind guiding angle of the first wind deflector unit (1) according to the wind speed so as to guide the airflow distribution on the surface of the heat exchanger (8). According to the scheme, the uniformity of the surface wind speed distribution of the heat exchanger of the split floor type air conditioner is improved, so that the heat exchange efficiency of the split floor type air conditioner is improved.

Description

Control device and method of air conditioner and air conditioner

Technical Field

The present invention relates to an air conditioner, and more particularly, to an air conditioner control apparatus and method, and an air conditioner (such as a split floor type air conditioner), and more particularly, to an air conditioner control apparatus having a first air deflector unit, an air conditioner (such as a split floor type air conditioner) having the same, and a control method of the air conditioner.

Background

Along with the change of the new national standard, the energy efficiency is upgraded, and the air conditioner is required to have higher performance to meet the market demand; therefore, optimizing the air conditioner structure, improving the system configuration and improving the air duct efficiency are important contents for improving the performance, and the air duct system in the air conditioner operation process is always concerned and researched. Under the same air quantity, the more uniform the surface air speed distribution of the heat exchanger is, the higher the heat transfer coefficient is, the higher the heat exchange efficiency is, and the more advantageous the performance of the system is.

For the split floor type air conditioner, the surface heat transfer coefficient of the heat exchanger is low due to uneven surface wind speed distribution of the heat exchanger of the split floor type air conditioner, and the heat exchange efficiency is influenced.

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

Disclosure of Invention

The invention aims to provide a control device and a control method of an air conditioner and the air conditioner, which aim to solve the problem that the surface wind speed distribution of a heat exchanger of a split floor type air conditioner is not uniform, so that the heat exchange efficiency of the split floor type air conditioner is influenced, and achieve the effect of improving the heat exchange efficiency of the split floor type air conditioner by improving the uniformity of the surface wind speed distribution of the heat exchanger of the split floor type air conditioner.

The present invention provides a control device for an air conditioner, wherein the air conditioner comprises: a first air deflector unit; the first air deflector unit is arranged between a fan and a heat exchanger of the air conditioner, and the current air deflecting angle of the first air deflector unit can be adjusted; the control device of the air conditioner comprises: a detection unit and a control unit; the control unit is configured to control the current air guide angle of the first air deflector unit to be at a set angle under the condition that the air conditioner is started and operated; the detection unit is configured to detect the wind speed of the lower surface of the heat exchanger during the operation of the air conditioner; the control unit is configured to adjust the current wind guiding angle of the first wind deflector unit according to the wind speed so as to guide the airflow distribution on the surface of the heat exchanger.

In some embodiments, further comprising: the control unit is further configured to determine whether a wind sweeping action instruction sent by a user is received before the current wind guiding angle of the first wind deflector unit is adjusted according to the wind speed; the wind sweeping action instruction comprises the following steps: a first adjusting instruction capable of adjusting the current wind guide angle of the first wind guide plate unit; under the condition that a wind sweeping action instruction sent by a user is not received, the current wind guide angle of the first wind deflector unit is adjusted according to the wind speed, under the condition that the wind sweeping action instruction sent by the user is received, the current wind guide angle of the first wind deflector unit is adjusted according to the wind sweeping action instruction, so that the first wind deflector unit and a second wind deflector unit at the air outlet of the air conditioner form a double wind guide phenomenon, and the path of an air flow output from the air conditioner fan outlet to the air outlet of the air conditioner and flowing through the first wind deflector unit and the second wind deflector unit is adjusted; wherein, under the condition that receives the action command of sweeping the wind that the user sent, the action command of sweeping the wind still includes: and the second adjusting instruction can adjust the current air guide angle of the second air guide plate unit.

In some embodiments, the first air deflection unit comprises: more than two air deflectors; the air deflectors are arranged above the heat exchanger and correspondingly divide the surface of the heat exchanger into more than two areas; each air deflector of the more than two air deflectors can guide air to a corresponding area on the surface of the heat exchanger; the control unit adjusts the current wind guiding angle of the first wind deflector unit according to the wind speed, and the control unit comprises: determining an average wind speed value of wind speeds of two or more of the regions, and determining a relation between the wind speed of each of the two or more of the regions and the average wind speed value; and adjusting the current wind guide angle of the first wind deflector unit according to the relation between the wind speed of each of more than two areas and the average wind speed value.

In some embodiments, the adjusting, by the control unit, the current wind guiding angle of the first wind deflector unit according to a relationship between a wind speed of each of two or more of the regions and the average wind speed includes: if the wind speed of at least one of the more than two areas is equal to the average wind speed, controlling the current wind guiding angle of the wind deflector corresponding to the at least one area to be maintained at a set angle; if the wind speed of any one of the more than two areas is smaller than the average wind speed, controlling the current wind guide angle of the wind deflector corresponding to the area to be increased so as to deflect the wind deflector corresponding to the area towards the heat exchanger and guide the airflow to flow towards the heat exchanger; and if the wind speed of any one of the more than two areas is greater than the average wind speed, controlling the current wind guiding angle of the wind guide plate corresponding to the area to be adjusted to be small, and enabling the airflow to flow towards other areas adjacent to the area.

In some embodiments, the control unit adjusts a current wind guiding angle of the first wind deflector unit according to the wind speed, and further includes: after the current wind guide angle of the first wind deflector unit is adjusted, re-determining the wind speed average value of the wind speeds of more than two areas, and re-determining the relation between the wind speed of each area of more than two areas and the wind speed average value; and readjusting the current wind guide angle of the first wind deflector unit according to the relationship between the wind speed of each of the more than two regions and the average wind speed value.

In some embodiments, the first air deflection unit further comprises: the motor is matched with each air deflector; the control unit controls the current wind guide angle of one wind deflector matched with one motor by controlling the rotation of one motor.

In some embodiments, the first air deflection unit further comprises: the crankshaft support rod, the crankshaft and the motor support rod; the crankshaft supporting rod and the motor supporting rod are arranged in parallel; the air deflectors are arranged between the crankshaft support rod and the motor support rod in parallel; the crankshaft is arranged between the crankshaft support rod and the first end of the air deflector; the motor is arranged between the motor supporting rod and the second end of the air deflector.

In some embodiments, at least one of two or more of the wind deflectors comprises: honeycomb aviation baffle.

In accordance with another aspect of the present invention, there is provided an air conditioner including: the control device of the air conditioner is described above.

In a method for controlling an air conditioner, the air conditioner includes: a first air deflector unit; the first air deflector unit is arranged between a fan and a heat exchanger of the air conditioner, and the current air deflecting angle of the first air deflector unit can be adjusted; the control method of the air conditioner comprises the following steps: under the condition that the air conditioner is started and operated, controlling the current air guide angle of the first air guide plate unit to be at a set angle; detecting the wind speed of the lower surface of the heat exchanger in the running process of the air conditioner; and adjusting the current wind guide angle of the first wind deflector unit according to the wind speed so as to guide the airflow distribution on the surface of the heat exchanger.

In some embodiments, further comprising: before the current wind guiding angle of the first wind deflector unit is adjusted according to the wind speed, whether a wind sweeping action instruction sent by a user is received or not is determined; the wind sweeping action instruction comprises the following steps: a first adjusting instruction capable of adjusting the current wind guide angle of the first wind guide plate unit; under the condition that a wind sweeping action instruction sent by a user is not received, adjusting the current wind guiding angle of the first wind deflector unit according to the wind speed; under the condition that a wind sweeping action instruction sent by a user is received, adjusting the current wind guide angle of the first wind guide plate unit according to the wind sweeping action instruction so as to enable the first wind guide plate unit and a second wind guide plate unit at the air outlet of the air conditioner to form a double wind guide phenomenon, and adjusting the path of an air flow output from the air conditioner fan outlet to the air outlet of the air conditioner to flow through the first wind guide plate unit and the second wind guide plate unit; wherein, under the condition that receives the action command of sweeping the wind that the user sent, sweep the wind action command, still include: and the second adjusting instruction can adjust the current air guide angle of the second air guide plate unit.

In some embodiments, the first air deflection unit comprises: more than two air deflectors; the air deflectors are more than two, and correspondingly divide the surface of the heat exchanger into more than two areas; each air deflector of the more than two air deflectors can guide air to a corresponding area on the surface of the heat exchanger; adjusting the current wind guiding angle of the first wind deflector unit according to the wind speed, wherein the adjusting comprises the following steps: determining an average wind speed value of wind speeds of two or more of the regions, and determining a relation between the wind speed of each of the two or more of the regions and the average wind speed value; and adjusting the current wind guide angle of the first wind deflector unit according to the relation between the wind speed of each of more than two areas and the average wind speed value.

In some embodiments, adjusting the current wind guiding angle of the first wind deflector unit according to the relationship between the wind speed of each of two or more of the zones and the average wind speed value comprises: if the wind speed of at least one of the more than two areas is equal to the average wind speed value, controlling the current wind guide angle of the wind deflector corresponding to the at least one area to be maintained at a set angle; if the wind speed of any one of the more than two areas is smaller than the average wind speed value, controlling the current wind guide angle of the wind deflector corresponding to the area to be increased so as to deflect the wind deflector corresponding to the area towards the direction of the heat exchanger and guide the airflow to flow towards the direction of the heat exchanger; and if the wind speed of any one of the more than two areas is greater than the average wind speed, controlling the current wind guiding angle of the wind guide plate corresponding to the area to be adjusted to be small, and enabling the airflow to flow towards other areas adjacent to the area.

In some embodiments, adjusting the current wind guiding angle of the first wind deflector unit according to the wind speed further comprises: after the current wind guiding angle of the first wind deflector unit is adjusted, re-determining the wind speed average value of the wind speeds of more than two areas, and re-determining the relation between the wind speed of each area of the more than two areas and the wind speed average value; and readjusting the current wind guide angle of the first wind deflector unit according to the relationship between the wind speed of each of the more than two regions and the average wind speed value.

Therefore, according to the scheme of the invention, the first air deflector unit is arranged between the fan and the heat exchanger of the split floor type air conditioner, the air deflection angle of the first air deflector unit is adjusted according to the detected air velocity to guide the air flow distribution, so that the air velocity distribution on the surface of the heat exchanger is uniform, and the heat exchange efficiency of the split floor type air conditioner is improved by improving the uniformity of the air velocity distribution on the surface of the heat exchanger of the split floor type air conditioner.

Further, according to the scheme of the invention, the first air deflector unit is arranged between the fan and the heat exchanger of the split floor type air conditioner, the opening angle or the air deflection angle of the air deflector in the first air deflector unit is controlled according to actual requirements, so that the first air deflector unit and the second air deflector unit, namely the second air deflector unit at the air outlet, form a double air deflection phenomenon, the path of air flow flowing through the first air deflector unit and the second air deflector unit is changed, the air outlet direction, the air outlet quantity and the air outlet range of the air outlet air flow can be adjusted, and the body feeling comfort level of a user is improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

Fig. 1 is a schematic structural diagram of a control device of an air conditioner according to an embodiment of the present invention;

fig. 2 is a side view of an embodiment of the first air guiding plate unit at the indoor unit position;

FIG. 3 is a schematic view illustrating the air flowing direction when the first and second air guiding plate units are operated

Fig. 4 is a schematic view of the direction of air flow in a related arrangement;

FIG. 5 is a schematic structural view of an embodiment of a first air guiding plate unit;

FIG. 6 is a logic flow diagram of an embodiment of a first air guiding plate unit;

FIG. 7 is a flowchart illustrating a control method of an air conditioner according to an embodiment of the present invention;

fig. 8 is a flowchart illustrating an embodiment of determining an adjustment manner of a current wind guiding angle of the first wind guiding plate unit in the method of the present invention;

fig. 9 is a flowchart illustrating an embodiment of a first process of adjusting the current wind guiding angle of the first wind guiding plate unit 1 according to the wind speed in the method of the present invention;

fig. 10 is a flowchart illustrating a second process of adjusting the current wind guiding angle of the first wind guiding plate unit 1 according to the wind speed in the method of the present invention.

The reference numbers in the embodiments of the present invention are as follows, in combination with the accompanying drawings:

1-a first air deflector unit (i.e. the first air deflector unit between the heat exchanger and the rear side plate); 2-a volute; 3-centrifugal fan blades; 4-a fan; 5-air inlet; 6-a baffle plate; 7-a second air deflector unit (namely, the second air deflector unit at the air outlet); 8-a heat exchanger; 9-rear side plate; 10-crankshaft support rods; 11-a crankshaft; 12-a stepper motor; 13-a honeycomb air deflector; 14-a motor support bar; 15-rear side panel high velocity zone.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

According to an embodiment of the present invention, there is provided a control apparatus of an air conditioner. Referring to fig. 1, a schematic diagram of an embodiment of the apparatus of the present invention is shown. The air conditioner includes: a first air deflector unit 1. The first air deflector unit 1 is arranged between the fan 4 and the heat exchanger 8 of the air conditioner, and the current air deflection angle of the first air deflector unit 1 can be adjusted. The control device of the air conditioner comprises: a detection unit and a control unit.

The control unit is configured to control the current wind guiding angle of the first wind deflector unit 1 to be at a set angle (for example, the wind guiding angle when the wind deflector is in a horizontal state) when the air conditioner is started and operated. Specifically, the air conditioner is electrified to normally operate, and meanwhile, the motor control module is electrified to control the motor to drive the air deflector to be in a horizontal state.

The detection unit is configured to detect the wind speed on the lower surface of the heat exchanger 8 during the operation of the air conditioner.

The control unit is configured to adjust the current wind guiding angle of the first wind deflector unit 1 according to the wind speed under the condition that a wind sweeping action instruction sent by a user is not received, so as to guide the airflow distribution on the surface of the heat exchanger 8 and enable the wind speed on the surface of the heat exchanger 8 to tend to be uniform.

Specifically, the comfort level is adjusted in a synchronous and auxiliary manner with the main purposes of controlling the surface wind speed distribution uniformity of a heat exchanger (such as the heat exchanger 8 in fig. 3) and improving the heat exchange efficiency. Therefore, the opening angle or the air guide angle of the air guide plates in the first air guide plate unit can be automatically adjusted according to the air speed detection result through the first air guide plate unit to guide air flow distribution, the problem that the surface air speed distribution of a heat exchanger (such as the heat exchanger 8 in the figure 3) is not uniform is solved, and the air speed and the air volume on the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3) are reasonably distributed.

Therefore, the first air deflector unit 1 is additionally arranged between the fan 4 and the heat exchanger 8 of the split floor type air conditioner (such as a square cabinet air conditioner), namely the first air deflector unit 1 is additionally arranged between the heat exchanger and the rear side plate, and the opening angle or the air guide angle of the air deflector in the first air deflector unit 1 is automatically adjusted according to the detected air speed so as to guide the air flow distribution, so that the problem of uneven surface air speed distribution of the heat exchanger is solved, the heat exchange efficiency of an air conditioning system is improved, and the air conditioning performance is improved.

In some embodiments, the air conditioner further comprises: a second air deflection unit 7. And the second air deflector unit 7 is arranged at the air outlet of the air conditioner. The control device of the air conditioner further comprises: the process of determining the current air guide angle adjusting mode of the first air guide plate unit specifically includes the following steps:

the control unit is further configured to determine whether a wind sweeping action instruction sent by a user is received before the current wind guiding angle of the first wind deflector unit 1 is adjusted according to the wind speed. The wind sweeping action instruction comprises the following steps: and the first adjusting instruction is sent by a user and can adjust the current air guide angle of the first air guide plate unit 1. And the number of the first and second groups,

the control unit is also configured to adjust the current wind guiding angle of the first wind deflector unit 1 according to the wind speed under the condition that a wind sweeping action instruction sent by a user is not received,

the control unit is further configured to adjust a current air guide angle of the first air deflector unit 1 according to a wind sweeping action instruction sent by a user under the condition that the wind sweeping action instruction is received, so that the first air deflector unit 1 and the second air deflector unit 7 at the air outlet of the air conditioner form a double air guide phenomenon, adjust a path of an air flow output from the outlet of the air conditioner fan 4 to the air outlet of the air conditioner to flow through the first air deflector unit 1 and the second air deflector unit 7, and adjust an air outlet direction, an air outlet amount and an air outlet range of the air outlet air flow output from the air outlet of the air conditioner.

Wherein, under the condition that receives the action command of sweeping the wind that the user sent, sweep the wind action command, still include: and a second adjusting instruction which is sent by the user and can adjust the current air guide angle of the second air guide plate unit 7. In the actual use process, the opening angle or the air guide angle of the second air guide plate unit can be adjusted according to the actual requirements of users. When a wind sweeping action command sent by a user is received, the wind sweeping action command is an adjusting command which is sent by the user and can adjust at least one of the current wind guiding angle of the first wind guiding plate unit 1 and the second wind guiding plate unit 7.

Specifically, without detecting the wind speed, a user sends a wind sweeping command according to actual needs, the air deflector unit operates according to a set wind sweeping angle, a first air deflector unit and a second air deflector unit are combined to form a double air deflecting phenomenon of the first air deflector unit and the second air deflector unit, when airflow flows through the first air deflector unit, the direction of the airflow entering a heat exchanger (such as a heat exchanger 8 in fig. 3) is changed, the distribution state of the original airflow is interfered, an airflow increasing or decreasing effect can be formed with the second air deflector unit, and the air outlet direction, the air outlet amount and the air outlet range of the airflow are further adjusted. And default, when the air conditioner operates, the motor control module automatically adjusts, detects and adjusts the angle of the air deflector according to the wind speed detection result unless a user remote control wind sweeping command is received.

For example: when a wind sweeping action instruction is received, the motor control module does not detect a wind speed value, and controls the stepping motor to drive the air deflector to return to a default state, the motors in all the regions operate integrally according to a set angle, the air deflector in each region is driven by the motors to sweep wind according to the set angle (if the set angle is 20-160 degrees), until a wind sweeping pause instruction is received, the motor control module controls the motors to stop acting to drive the air deflector to stop sweeping, and the air conditioner keeps the air deflector to continuously operate at the angle.

Therefore, by adding the first air deflector unit between the fan (e.g., the fan 4 in fig. 3) and the heat exchanger (e.g., the heat exchanger 8 in fig. 3) of the split floor type air conditioner (e.g., the square cabinet), that is, the first air deflector unit (e.g., the first air deflector unit 1 in fig. 2) added between the heat exchanger and the rear side plate, a user can control an opening angle or an air deflection angle of the air deflector in the first air deflector unit according to actual needs, and a double air deflection phenomenon is formed with the second air deflector unit (e.g., the second air deflector unit 7 in fig. 3) at the air outlet, so that a path through which air flows through the first air deflector unit and the second air deflector unit is changed, the air outlet direction, the air outlet amount and the air outlet range of the air outlet airflow can be adjusted, and the comfort level of the user is improved.

In some embodiments, the first air deflection unit 1 includes: more than two air deflectors. The more than two air deflectors correspondingly divide the surface of the heat exchanger 8 into more than two areas. Each of the two or more air deflectors is capable of guiding air to a corresponding area on the surface of the heat exchanger 8.

Specifically, the first air deflector unit can guide the high wind speed of the rear side plate (such as the rear side plate 9 in fig. 3) to the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3), and relieve the wind speed deviation between the rear side plate (such as the rear side plate 9 in fig. 3) and the heat exchanger (such as the heat exchanger 8 in fig. 3) so as to enhance the heat exchange effect of the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3).

The first air deflector unit (for example, the first air deflector unit 1 in fig. 2) is arranged behind the air outlet section of the fan (for example, the fan 4 in fig. 3) and in front of the air inlet section of the heat exchanger (for example, the heat exchanger 8 in fig. 3), forms a certain angle δ with the rear side plate, and is fixed on the left side plate and the right side plate. The first air deflector unit is composed of N air deflectors, such as a first air deflector, a second air deflector, a third air deflector, a fourth air deflector, a fifth air deflector, a so-speak so as to divide the surface of a heat exchanger (such as the heat exchanger 8 in fig. 3) into N areas such as a first area N1, a second area N2, a third area N3, a fourth area N4, a fifth area N5, a so-speak so as to form an N area Nn correspondingly, each air deflector corresponds to one area, for example, the first air deflector corresponds to the first area N1, the second air deflector corresponds to the second area N2 and the like, and N is a positive integer.

The control unit, when not receiving the wind sweeping action command sent by the user, adjusts the current wind guiding angle of the first wind deflector unit 1 according to the wind speed, and comprises:

the control unit is further configured to determine a wind speed average of wind speeds for two or more of the zones, and determine a relationship between the wind speed for each of the two or more zones and the wind speed average.

The control unit is specifically configured to adjust the current wind guiding angle of the first wind deflector unit 1 according to a relationship between the wind speed of each of the two or more areas and the average wind speed value.

Specifically, each area is provided with a wind speed detector. And when the wind sweeping action command is not received, the motor control module obtains the wind speed average value beta of the wind speed of each area according to the wind speed fed back by the wind speed detectors of each area. Determining whether the wind speed values eta 1, eta 2 and … … of the regions N1, N2 and … … are equal to the wind speed average value beta, namely determining the wind speed value eta of the i-th region_iAnd whether the current wind guiding angle is equal to beta or not is judged, and the current wind guiding angle of the first wind guiding plate unit 1 is adjusted according to the judgment result.

And when the air conditioner runs, automatically detecting the wind speed according to the default set control method. That is, after the motor module automatically detects wind speeds η of various regions, an average wind speed value β is obtained, when the wind speed η of each region on the surface of the heat exchanger (e.g., the heat exchanger 8 in fig. 3) is greater than (or less than or equal to) the average wind speed value β, the motor control module individually controls the rotation of the motor of each region according to the different wind speeds of each region, so as to control the angles of the air deflectors of each region, guide the air flow distribution, and synchronously guide the high wind speed of the rear side plate to the surface of the heat exchanger (e.g., the heat exchanger 8 in fig. 3), so that the wind speed on the surface of the heat exchanger (e.g., the heat exchanger 8 in fig. 3) is increased. The purposes of adjusting the surface wind speed uniformity of a heat exchanger (such as a heat exchanger 8 in the figure 3) and increasing the wind speed are synchronously achieved, and the heat exchange effect is enhanced.

In some embodiments, the control unit adjusts the current wind guiding angle of the first wind deflector unit 1 according to the relationship between the wind speed of each of two or more of the zones and the average wind speed, and includes any one of the following adjustment situations:

the first adjustment scenario: and if the wind speed of at least one of the more than two areas is equal to the average wind speed value, controlling the current wind guide angle of the wind guide plate corresponding to the at least one area to be maintained at a set angle.

Specifically, the wind speed value eta detected if a certain region or a plurality of regions are synchronous_iWhen the wind speed average value β is obtained, the motor control module controls the stepping motor in the area to be inactive, and the air guide plate in the area maintains the original state (the default horizontal state is maintained in the first detection).

The second adjustment scenario: if the wind speed of any one of the more than two areas is smaller than the average wind speed, controlling the current wind guiding angle of the wind deflector corresponding to the area to be increased so as to deflect the wind deflector corresponding to the area towards the heat exchanger 8 and guide the airflow to flow towards the heat exchanger 8.

Specifically, if the wind speed value eta detected in a certain region_iWhen the wind speed average value is not equal to the wind speed average value beta, the motor control module controls the stepping motor in the area to act to drive the air deflector in the area to rotate so as to enable the wind speed eta in the area to rotate_iAnd the current latest calculated wind speed average value beta is approached. Wind speed value eta as detected when a certain region_iIf the wind speed average value beta is less than the wind speed average value beta, the motor control module automatically controls the motor in the area to rotate, the opening angle of the air deflector in the area is adjusted to increase the wind speed, namely the air deflector in the area is controlled to deflect towards the heat exchanger (such as the heat exchanger 8 in the figure 3), the air flow is guided to flow towards the heat exchanger (such as the heat exchanger 8 in the figure 3), and at the moment, the wind speed detector synchronously detects the wind speed value eta of the air deflector in the area after the opening angle is adjusted_iAnd sending a signal to a motor control module, and adjusting the opening angle of an air deflector in the area to obtain a wind speed value eta_iAnd when the required value (namely the currently and newly calculated wind speed average value beta) is reached, the motor is controlled to stop moving.

The third adjustment case: and if the wind speed of any one of the more than two areas is greater than the average wind speed, controlling the current wind guiding angle of the wind guide plate corresponding to the area to be adjusted to be small, and enabling the airflow to flow towards other areas adjacent to the area.

Specifically, the wind speed value eta detected in a certain region_iAdjusting the opening of the air deflector in the area more than the average wind speed betaThe starting angle reduces the wind speed, so that the airflow flows to the nearby area, and the effect of increasing the wind speed of the nearby area is achieved. For example: the wind speed value eta detected when the second region is_iThe wind speed is reduced by adjusting the opening angle of the second air deflector, so that the air flow flows to the side area, and the effect of increasing the wind speed of the nearby area is achieved. The side area is a side area of the second area, such as the first area, the third area, the fourth area, the fifth area, and so on.

In some embodiments, the control unit, when not receiving a wind sweeping motion command sent by a user, adjusts a current wind guiding angle of the first wind deflector unit 1 according to the wind speed, and further includes:

the control unit is specifically further configured to, after adjusting the current wind guiding angle of the first wind deflector unit 1, re-determine a wind speed average value of wind speeds of two or more of the areas, and re-determine a relationship between the wind speed of each of the two or more of the areas and the wind speed average value.

The control unit is specifically further configured to readjust the current wind guiding angle of the first wind deflector unit 1 according to the re-determined relationship between the wind speed of each of the two or more regions and the average wind speed value.

Specifically, after the wind guiding angle of the first wind deflector unit is adjusted each time, the wind speed value η of each area detected in real time is determined again_iThe wind speed average β is recalculated. The opening angle of the air deflector is adjusted in real time through the control, the air deflector is circularly reciprocated, the average value of the detected air speed is continuously updated so as to achieve the aim of uniformity of the air speed of each area, the high-speed area 15 of the rear side plate is synchronously utilized, and the heat exchange effect is improved.

In some embodiments, the first air deflection unit 1 further comprises: and a motor (such as a stepping motor 12) matched with each air deflector. Namely, each air deflector is matched with one motor, and the control unit controls the current air deflection angle of one air deflector matched with one motor by controlling the rotation of one motor.

Specifically, each air deflector is connected to a motor control module through a stepping motor, and the motor control module controls the rotation of the motor to control the opening angle of the air deflector.

In some embodiments, the first air deflection unit 1 further comprises: a crankshaft support rod 10, a crankshaft 11 and a motor support rod 14.

Wherein the crankshaft support rod 10 and the motor support rod 14 are arranged in parallel. And the more than two air deflectors are arranged between the crankshaft support rod 10 and the motor support rod 14 in parallel.

And the crankshaft 11 is arranged between the crankshaft support rod 10 and the first end of the air deflector. The motor is arranged between the motor support rod 14 and the second end of the air deflector.

In some embodiments, at least one of two or more of the wind deflectors comprises: and a honeycomb air deflector 13.

Specifically, the crankshaft support rod 10 and the motor support rod 14 are arranged in parallel. And a plurality of honeycomb air deflectors 13 arranged in parallel between the crankshaft support rod 10 and the motor support rod 14. And the crankshaft 11 is arranged between the crankshaft support rod 10 and the honeycomb air deflector 13. The stepping motor 12 is arranged between the motor supporting rod 14 and the honeycomb air deflector 13.

Through a large number of tests, the technical scheme of the invention is adopted, the first air deflector unit is arranged between the fan and the heat exchanger of the split floor type air conditioner, the air deflection angle of the first air deflector unit is adjusted according to the detected air velocity to guide the air flow distribution, so that the air velocity distribution on the surface of the heat exchanger is uniform, and the heat exchange efficiency of the split floor type air conditioner is improved by improving the uniformity of the air velocity distribution on the surface of the heat exchanger of the split floor type air conditioner.

According to an embodiment of the present invention, there is also provided an air conditioner corresponding to a control device of the air conditioner. The air conditioner may include: the control device of the air conditioner is described above.

In a related scheme, the indoor unit of the split floor type air conditioner is provided with a rear side plate (such as a rear side plate 9 in fig. 3), and the lower part of the indoor unit is provided with a fan (such as a fan 4 in fig. 3) and an indoor air inlet (such as an air inlet 5 in fig. 3); the upper part is provided with an indoor heat exchanger (such as a heat exchanger 8 in figure 3) and an indoor air outlet. A heat exchanger (e.g., heat exchanger 8 in fig. 3) is typically placed on the rear side plate (e.g., rear side plate 9 in fig. 3) at an angle θ in the vertical direction, with the heat exchanger (e.g., heat exchanger 8 in fig. 3) at the rear side plate (e.g., rear side plate 9 in fig. 3). When the air conditioner works, indoor air is sucked and blown out through an air inlet (such as an air inlet 5 in a figure 3) and a fan (such as a fan 4 in a figure 3), and airflow flows through a heat exchanger (such as a heat exchanger 8 in a figure 3) and then flows out of an air outlet to the indoor space, so that the indoor air treatment process is completed.

Because the heat exchanger (e.g., the heat exchanger 8 in fig. 3) and the rear side plate (e.g., the rear side plate 9 in fig. 3) form a certain angle θ, the air at the air inlet (e.g., the air inlet 5 in fig. 3) is accelerated by the fan, and when flowing through the heat exchanger (e.g., the heat exchanger 8 in fig. 3) along the air duct, the closer to the rear side plate, the higher the air speed, and the lower the air speed on the surface of the heat exchanger (e.g., the heat exchanger 8 in fig. 3), i.e., the high air speed close to the rear side plate (e.g., the rear side plate 9 in fig. 3) is not effectively utilized, and the surface of the heat exchanger (e.g., the heat exchanger 8 in fig. 3) is unevenly distributed due to the air speed, so that the heat transfer coefficient on the surface of the heat exchanger (e.g., the heat exchanger 8 in fig. 3) is lower, the heat exchange efficiency is affected, and the performance of the split-floor type air conditioner is affected; in addition, the uneven distribution of the wind speed on the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3) synchronously influences the distribution of the airflow at the air outlet, thereby influencing the body feeling comfort of human bodies at different temperatures and different positions.

In some schemes, an air distribution structure is arranged between an indoor unit fan and a heat exchanger, after the fan introduces air flow, the air flow flows through the air distribution structure, the air distribution structure disperses the air flow according to the self-arranged position, the air velocity gradient of a high-speed area and a low-speed area is relieved to a certain extent by dispersing the air flow, the air velocity difference is reduced, the air velocity adjustment flexibility of the surface of the heat exchanger is weaker, and the high air velocity of a rear side plate cannot be effectively introduced to the surface of the heat exchanger, so that the air distribution structure cannot be fully utilized.

In some schemes, an air deflector is arranged between a fan and a heat exchanger, an air guide surface of the air deflector is arranged in an inclined windward mode relative to the air conveying direction of an outlet of the fan to the heat exchanger, air can be guided to the heat exchanger through the air guide function of the air deflector, heat exchange can be enhanced to a certain extent, however, the air deflector is fixed on a rear side plate at a specific angle and cannot be automatically adjusted according to the change of an actual wind field, and the effect of uniformly adjusting the wind speed of the upper portion and the lower portion of the surface of the heat exchanger is not strong.

In some schemes, a fixed air deflector is additionally arranged at the rear side plate similarly, the air deflector extends to the bottom of the heat exchanger, and the high air speed of the rear side plate is enhanced to guide and guide the flow.

Fig. 2 is a side view of the first air guiding plate unit in the indoor unit position. As shown in fig. 2, in the split floor type air conditioner (such as a square cabinet), the first air deflector unit 1 is disposed between a fan (such as fan 4 in fig. 3) and a heat exchanger (such as heat exchanger 8 in fig. 3).

In the example shown in fig. 2, θ is an included angle between the heat exchanger and the rear side plate, and the square cabinet machines in the related schemes should have angles; delta is the included angle between the first air deflector unit and the rear side plate, and because the heat exchanger and the rear side plate are obliquely arranged, the first air deflector unit also provides an oblique angle (delta is more than 0 and less than theta), so that the air flow is better guided to the surface of the heat exchanger.

Fig. 3 is a schematic view illustrating a flow direction of air when the first air guiding plate unit and the second air guiding plate unit are operated. As shown in fig. 3, in the split floor type air conditioner (e.g., a square cabinet), an air inlet 5 is provided below the heat exchanger 8. A volute 2, a centrifugal fan blade 3 and a fan 4 are also arranged below the heat exchanger 8 in a matching manner. A first air deflector unit 1 is arranged between the fan 4 and the heat exchanger 8, and a second air deflector unit 7 is arranged at the air outlet. Between the heat exchanger 8 and the second air deflection unit 7, a baffle 6 is also provided.

Fig. 4 is a schematic view showing the direction of air flow in the related art. In the example shown in fig. 4, the evaporator surface wind speed is lower than the rear-side panel wind speed in the rear-side panel high velocity region 15.

In some embodiments, according to the scheme of the present invention, a first air deflector unit is added between a fan (e.g., fan 4 in fig. 3) and a heat exchanger (e.g., heat exchanger 8 in fig. 3) of a split floor type air conditioner (e.g., a square cabinet air conditioner), that is, a first air deflector unit (e.g., first air deflector unit 1 in fig. 2) is added between the heat exchanger and a rear side plate, and a control method thereof is provided, so that on one hand, the first air deflector unit can automatically adjust an opening angle or an air deflection angle of an air deflector in the first air deflector unit according to a detected wind speed to guide air flow distribution, thereby solving a problem of uneven distribution of wind speed on the surface of the heat exchanger, further improving heat exchange efficiency of the air conditioning system, and improving air conditioning performance; on the other hand, a user can control the opening angle or the air guide angle of the air guide plates in the first air guide plate unit according to actual requirements, and the double air guide phenomenon is formed by the opening angle or the air guide angle and a second air guide plate unit (such as a second air guide plate unit 7 in fig. 3) at an air outlet of the second air guide plate unit, so that the path of air flow flowing through the first air guide plate unit and the second air guide plate unit is changed, the air outlet direction, the air outlet amount and the air outlet range of the air outlet flow can be adjusted, and the body feeling comfort level of the user is improved.

The opening angle or the air guide angle of the second air guide plate unit can be adjusted according to the actual requirement of a user.

Specifically, the present invention provides a first air deflector unit of a square cabinet, an air conditioner and a control method thereof, which are mainly used for controlling the uniformity of the surface air speed distribution of a heat exchanger (e.g., the heat exchanger 8 in fig. 3) and improving the heat exchange efficiency, and synchronously and auxiliarily adjusting the comfort level. Therefore, the opening angle or the air guide angle of the air guide plates in the first air guide plate unit can be automatically adjusted according to the air speed detection result through the first air guide plate unit to guide air flow distribution, the problem that the surface air speed distribution of a heat exchanger (such as the heat exchanger 8 in the figure 3) is not uniform is solved, and the air speed and the air volume on the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3) are reasonably distributed.

According to the scheme of the invention, the first air deflector unit is provided, so that high wind speed of the rear side plate (such as the rear side plate 9 in fig. 3) can be guided to the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3), and wind speed deviation between the rear side plate (such as the rear side plate 9 in fig. 3) and the heat exchanger (such as the heat exchanger 8 in fig. 3) is relieved, so that the heat exchange effect of the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3) is enhanced.

The first air deflector unit (such as the first air deflector unit 1 in fig. 2) is arranged behind the air outlet section of the fan (such as the fan 4 in fig. 3) and in front of the air inlet section of the heat exchanger (such as the heat exchanger 8 in fig. 3), forms a certain angle with the rear side plate, and is fixed on the left side plate and the right side plate. The first air deflector unit is composed of N air deflectors, such as a first air deflector, a second air deflector, a third air deflector, a fourth air deflector, a fifth air deflector, a so-speak so as to divide the surface of a heat exchanger (such as the heat exchanger 8 in fig. 3) into N areas such as a first area N1, a second area N2, a third area N3, a fourth area N4, a fifth area N5, a so-speak so as to form an N area Nn correspondingly, each air deflector corresponds to one area, for example, the first air deflector corresponds to the first area N1, the second air deflector corresponds to the second area N2 and the like, and N is a positive integer.

Wherein, each area is provided with a wind speed detector, and the wind speed detector is arranged at the middle position of each area (N1, N2 … … Nn) on the lower surface of the heat exchanger. Each air deflector is connected to a motor control module through a stepping motor, and the motor is controlled to rotate through the motor control module to control the opening angle of the air deflector.

On one hand, when the air conditioner runs, the air speed is defaulted to be automatically detected according to a set control method; after the motor module automatically detects the wind speeds eta of all the regions, the wind speed average value beta is obtained, when the wind speeds eta of all the regions on the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3) are larger than (or smaller than or equal to) the wind speed average value beta, the motor control module independently controls the motors of all the regions to rotate according to the different wind speeds of all the regions, so that the angles of the air deflectors of all the regions are controlled, the air flow distribution is guided, the high wind speed of the rear side plate is synchronously guided to the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3), and the surface wind speed of the heat exchanger (such as the heat exchanger 8 in the figure 3) is improved; the purposes of adjusting the surface wind speed uniformity of a heat exchanger (such as a heat exchanger 8 in the figure 3) and increasing the wind speed are synchronously achieved, and the heat exchange effect is enhanced.

On the other hand, the wind speed can not be detected, a user sends a wind sweeping command according to actual needs, the air deflector unit operates according to a set wind sweeping angle, a first air deflector unit and a second air deflector unit are combined to form a double air deflecting phenomenon of the first air deflector unit and the second air deflector unit, when air flows through the first air deflector unit, the direction of the air entering the heat exchanger (such as the heat exchanger 8 in the figure 3) is changed, the distribution state of original air flow is interfered, an air flow increasing or weakening effect can be formed with the second air deflector unit, and the air flow outlet direction, the air outlet quantity and the air outlet range are further adjusted.

And default, when the air conditioner operates, the motor control module automatically adjusts, detects and adjusts the angle of the air deflector according to the wind speed detection result unless a user remote control wind sweeping command is received.

The scheme of the invention also provides the air conditioner, which solves the problem of low performance caused by low heat exchange capacity of the air conditioner, and improves the heat exchange efficiency of a heat exchanger (such as the heat exchanger 8 in the figure 3) so as to improve the performance of the air conditioner.

The scheme of the invention also provides an air conditioner, the air outlet direction, the air outlet quantity and the air outlet range of the air outlet flow are adjusted by changing the path of the air flow flowing through the first air deflector unit and the second air deflector unit, for example, the air conditioner can generate the air flow sinking phenomenon in the refrigeration mode, the first air deflector unit guides the high air speed of the rear side plate to the heat exchanger, meanwhile, the first air deflector unit provides great thrust to the air flow flowing through the heat exchanger, in addition, the sinking air flow can be lifted by the upward air guiding angle, and the air flow sinking phenomenon is relieved, so the air quantity is further increased, the air outlet range is increased by matching with the second air deflector unit, the problem of limitation of guiding the air outlet by a single air deflector in related schemes is solved, and the effect of improving the user feeling comfort level is achieved.

Fig. 5 is a schematic structural diagram of an embodiment of the first air guiding plate unit. As shown in fig. 5, the first air deflection unit (e.g., the first air deflection unit 1 in fig. 2) includes: crankshaft support rod 10, crankshaft 11, step motor 12, honeycomb aviation baffle 13 and motor support rod 14. The crankshaft support rod 10 and the motor support rod 14 are arranged in parallel. And a plurality of honeycomb air deflectors 13 arranged in parallel between the crankshaft support rod 10 and the motor support rod 14. And the crankshaft 11 is arranged between the crankshaft support rod 10 and the honeycomb air deflector 13. The stepping motor 12 is arranged between the motor supporting rod 14 and the honeycomb air deflector 13.

FIG. 6 is a logic control flow diagram of an embodiment of an air deflector unit. As shown in fig. 6, the logic control flow of the air deflector unit includes:

step 1, electrifying an air conditioner to normally run, electrifying a motor control module at the same time, and controlling a motor to drive an air deflector to be in a horizontal state; because each air deflector in the first air deflector unit 1 is provided with the honeycomb holes, even if the air deflector is in a horizontal state, the air flow accelerated by the fan 4 can still flow through the honeycomb holes of the air deflector and reach the surface of the heat exchanger, and the influence on the air flow path when the air conditioner is just started is small.

And 2, judging whether a wind sweeping action instruction sent by a user is received, specifically, judging whether the wind sweeping action instruction of the first air deflector unit is received. For example: and the user sends a wind sweeping action command through a remote controller of the air conditioner.

Step 3, when the wind sweeping action instruction is not received, the motor control module obtains the wind speed average value beta of the wind speed of each area according to the wind speed fed back by the wind speed detectors of each area; judging whether the wind speed values eta 1, eta 2 and … … of the regions N1, N2 and … … are equal to the wind speed average value beta or not, namely judging the wind speed value eta of the i-th region_iWhether or not it is equal to β:

if the detected wind speed values eta of a certain region or a plurality of regions are synchronous_iWhen the wind speed average value β is obtained, the motor control module controls the stepping motor in the area to be inactive, and the air guide plate in the area maintains the original state (the default horizontal state is maintained in the first detection). After the wind guiding angle of the first wind guiding plate unit is adjusted every time, the wind guiding angle is adjusted again according to the real-time detected wind speed value eta of each area_iThe wind speed average β is recalculated.

If the wind speed detected in a certain area is eta_iWhen the wind speed average value is not equal to the wind speed average value beta, the motor control module controls the stepping motor in the area to act to drive the air deflector in the area to rotate so as to enable the wind speed eta in the area to rotate_iThe wind speed average value beta and the wind deflector rotation angle gamma (such as the angle gamma) which tend to be obtained by the current latest calculation₁、γ₂) From the wind speed η of the region_iAnd the wind speed tends to be determined by the current latest calculated wind speed average value beta. Each regionThe wind deflector rotates by an angle gamma under the drive of the motor₁、γ₂… …, etc.

When the wind speed detected in a certain area is eta_iIf the wind speed average value beta is less than the wind speed average value beta, the motor control module automatically controls the motor in the area to rotate, the opening angle of the air deflector in the area is adjusted to increase the wind speed, namely the air deflector in the area is controlled to deflect towards the direction of the heat exchanger (such as the heat exchanger 8 in the figure 3), and the airflow is guided to flow towards the direction of the heat exchanger (such as the heat exchanger 8 in the figure 3), at the moment, the wind speed detector synchronously detects the wind speed value eta of the air deflector in the area after the opening angle is adjusted_iAnd sending a signal to a motor control module, and adjusting the opening angle of an air deflector in the area to obtain a wind speed value eta_iAnd when the required value (namely the currently and newly calculated wind speed average value beta) is reached, the motor is controlled to stop moving.

Similarly, the wind speed value eta detected in a certain area_iIf the wind speed is larger than the average wind speed beta, the opening angle of the air deflector in the area is adjusted to reduce the wind speed, so that the airflow flows to the area beside the area, and the effect of increasing the wind speed of the nearby area is achieved.

For example: the wind speed value eta detected when the second region is_iIf the wind speed is larger than the average wind speed beta, the opening angle of the second air deflector is adjusted to reduce the wind speed, so that the air flow flows to the nearby area, and the effect of increasing the wind speed of the nearby area is achieved. The side area is a side area of the second area, such as the first area, the third area, the fourth area, the fifth area, and so on.

Therefore, the opening angle of the air deflector is adjusted in real time through the control, the air deflector is circularly reciprocated, the average value of the detected air speed is continuously updated so as to achieve the aim of uniformity of the air speed of each area, the high-speed area 15 of the rear side plate is synchronously utilized, and the heat exchange effect is improved.

And 4, when a wind sweeping action instruction is received, the motor control module does not detect a wind speed value, and controls the stepping motor to drive the air guide plate to return to a default state, the motors in all the regions operate integrally according to a set angle, the air guide plate in each region is driven by the motor to sweep wind according to the set angle (if the set angle is 20-160 degrees), and until a wind sweeping pause instruction is received, the motor control module controls the motor to stop acting to drive the air guide plate to stop sweeping wind, and the air conditioner keeps the air guide plate to continue to operate at the angle.

Since the processing and functions of the air conditioner of this embodiment are basically corresponding to the embodiments, principles and examples of the apparatus shown in fig. 1, reference may be made to the related descriptions in the foregoing embodiments without being repeated in detail in the description of this embodiment.

Through a large number of tests, the technical scheme of the invention is adopted, and the first air deflector unit is arranged between the fan and the heat exchanger of the split floor type air conditioner, and the air deflection angle of the first air deflector unit is adjusted according to the detected air speed so as to guide the air flow distribution, so that the air speed distribution on the surface of the heat exchanger is uniform, the problem of nonuniform air speed distribution on the surface of the heat exchanger can be solved, the heat exchange efficiency of an air conditioning system is improved, and the air conditioning performance is improved.

According to an embodiment of the present invention, there is also provided a control method of an air conditioner corresponding to the air conditioner, as shown in fig. 7, which is a schematic flow chart of an embodiment of the method of the present invention. The air conditioner includes: a first air deflector unit 1. The first air deflector unit 1 is arranged between the fan 4 and the heat exchanger 8 of the air conditioner, and the current air deflection angle of the first air deflector unit 1 can be adjusted. The control method of the air conditioner comprises the following steps: step S110 to step S130.

In step S110, when the air conditioner is started and operated, the current air guiding angle of the first air guiding plate unit 1 is controlled to be at a set angle (e.g., the air guiding angle when the air guiding plate is in a horizontal state). Specifically, the air conditioner is electrified to normally operate, and meanwhile, the motor control module is electrified to control the motor to drive the air deflector to be in a horizontal state.

In step S120, during the operation of the air conditioner, the wind speed of the lower surface of the heat exchanger 8 is detected.

In step S130, when a wind sweeping action command sent by a user is not received, the current wind guiding angle of the first wind deflector unit 1 is adjusted according to the wind speed to guide the airflow distribution on the surface of the heat exchanger 8, so that the wind speed on the surface of the heat exchanger 8 tends to be uniform.

Specifically, the comfort level is synchronously and auxiliarily adjusted with the main purposes of controlling the surface wind speed distribution uniformity of a heat exchanger (such as the heat exchanger 8 in fig. 3) and improving the heat exchange efficiency. Therefore, the opening angle or the air guide angle of the air guide plates in the first air guide plate unit can be automatically adjusted according to the air speed detection result through the first air guide plate unit to guide air flow distribution, the problem that the surface air speed distribution of a heat exchanger (such as the heat exchanger 8 in the figure 3) is not uniform is solved, and the air speed and the air volume on the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3) are reasonably distributed.

Therefore, the first air deflector unit 1 is additionally arranged between the fan 4 and the heat exchanger 8 of the split floor type air conditioner (such as a square cabinet air conditioner), namely the first air deflector unit 1 is additionally arranged between the heat exchanger and the rear side plate, and the opening angle or the air guide angle of the air deflector in the first air deflector unit 1 is automatically adjusted according to the detected air speed, so that the air flow distribution is guided, the problem of uneven distribution of the air speed on the surface of the heat exchanger is solved, the heat exchange efficiency of the air conditioning system is improved, and the air conditioning performance is improved.

In some embodiments, the air conditioner further comprises: a second air deflection unit 7. And the second air deflector unit 7 is arranged at the air outlet of the air conditioner.

The control method of the air conditioner further comprises the following steps: and determining the current wind guiding angle adjusting mode of the first wind guiding plate unit.

With reference to the flowchart of fig. 8, a specific process for determining the adjustment mode of the current wind guiding angle of the first wind guiding plate unit is further defined, which includes: step S210 to step S230.

Step S210, before adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed, determining whether a wind sweeping action instruction sent by a user is received. The wind sweeping action instruction comprises the following steps: and the first adjusting instruction is sent by a user and can adjust the current air guide angle of the first air guide plate unit 1.

And step S220, when the wind sweeping action command sent by the user is not received, adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed.

Step S230, under the condition that a wind sweeping action instruction sent by a user is received, adjusting a current wind guiding angle of the first wind guiding plate unit 1 according to the wind sweeping action instruction, so that the first wind guiding plate unit 1 and the second wind guiding plate unit 7 at the air outlet of the air conditioner form a double wind guiding phenomenon, adjusting a path through which an air flow output from the outlet of the air conditioner fan 4 to the air outlet of the air conditioner flows through the first wind guiding plate unit 1 and the second wind guiding plate unit 7, and being capable of adjusting an air outlet direction, an air outlet amount, and an air outlet range of an air outlet air flow output from the air outlet of the air conditioner.

Wherein, under the condition that receives the action command of sweeping the wind that the user sent, the action command of sweeping the wind still includes: and a second adjusting instruction which is sent by the user and can adjust the current air guide angle of the second air guide plate unit 7. In the actual use process, the opening angle or the air guide angle of the second air guide plate unit can be adjusted according to the actual requirements of users. When a wind sweeping action command sent by a user is received, the wind sweeping action command is an adjusting command which is sent by the user and can adjust at least one of the current wind guiding angle of the first wind guiding plate unit 1 and the second wind guiding plate unit 7.

Specifically, without detecting the wind speed, a user sends a wind sweeping command according to actual needs, the air deflector unit operates according to a set wind sweeping angle, a first air deflector unit and a second air deflector unit are combined to form a double air deflecting phenomenon of the first air deflector unit and the second air deflector unit, when airflow flows through the first air deflector unit, the direction of the airflow entering a heat exchanger (such as a heat exchanger 8 in fig. 3) is changed, the distribution state of the original airflow is interfered, an airflow increasing or decreasing effect can be formed with the second air deflector unit, and the air outlet direction, the air outlet amount and the air outlet range of the airflow are further adjusted. And when the air conditioner is in operation, the motor control module automatically adjusts, detects and adjusts the angle of the air deflector according to the wind speed detection result unless a user remote control wind sweeping instruction is received.

For example: when a wind sweeping action instruction is received, the motor control module does not detect a wind speed value, and controls the stepping motor to drive the air deflector to return to a default state, the motors in all the regions operate integrally according to a set angle, the air deflector in each region is driven by the motors to sweep wind according to the set angle (if the set angle is 20-160 degrees), until a wind sweeping pause instruction is received, the motor control module controls the motors to stop acting to drive the air deflector to stop sweeping, and the air conditioner keeps the air deflector to continuously operate at the angle.

Therefore, by adding the first air deflector unit between the fan (such as the fan 4 in fig. 3) and the heat exchanger (such as the heat exchanger 8 in fig. 3) of the split floor type air conditioner (such as the square cabinet air conditioner), that is, the first air deflector unit (such as the first air deflector unit 1 in fig. 2) added between the heat exchanger and the rear side plate, a user can control the opening angle or the air deflection angle of the air deflector in the first air deflector unit according to actual requirements, and forms a double air deflection phenomenon with the second air deflector unit (such as the second air deflector unit 7 in fig. 3) at the air outlet, so that the path of air flow passing through the first air deflector unit and the second air deflector unit is changed, the air outlet direction, the air outlet amount and the air outlet range of the air outlet air flow can be adjusted, and the comfort degree of the user is improved.

In some embodiments, the first air deflection unit 1 includes: more than two air deflectors. The more than two air deflectors correspondingly divide the surface of the heat exchanger 8 into more than two areas. Each of the two or more air deflectors can guide air to a corresponding area on the surface of the heat exchanger 8.

Specifically, the first air deflector unit can guide the high wind speed of the rear side plate (such as the rear side plate 9 in fig. 3) to the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3), and relieve the wind speed deviation between the rear side plate (such as the rear side plate 9 in fig. 3) and the heat exchanger (such as the heat exchanger 8 in fig. 3) so as to enhance the heat exchange effect of the surface of the heat exchanger (such as the heat exchanger 8 in fig. 3).

The first air deflector unit (such as the first air deflector unit 1 in fig. 2) is arranged behind the air outlet section of the fan (such as the fan 4 in fig. 3) and in front of the air inlet section of the heat exchanger (such as the heat exchanger 8 in fig. 3), forms a certain angle with the rear side plate, and is fixed on the left side plate and the right side plate. The first air deflector unit is composed of N air deflectors, such as a first air deflector, a second air deflector, a third air deflector, a fourth air deflector, a fifth air deflector, a so-speak so as to divide the surface of a heat exchanger (such as a heat exchanger 8 in fig. 3) into N areas correspondingly, such as a first area N1, a second area N2, a third area N3, a fourth area N4, a fifth area N5, a so-speak so as to form an N area Nn, each air deflector corresponds to one area, such as the first air deflector corresponds to the first area N1, the second air deflector corresponds to the second area N2, and the N is a positive integer.

When the wind sweeping action command sent by the user is not received, the adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed in step S130 includes: and adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed.

With reference to the flowchart of fig. 9, a specific process of the first process of adjusting the current wind guiding angle of the first wind guiding plate unit 1 according to the wind speed in step S130 is further described, where the first process includes: step S310 and step S320.

Step S310, determining a wind speed average value of wind speeds of more than two areas, and determining a relation between the wind speed of each area of the more than two areas and the wind speed average value.

Step S310, adjusting the current wind guiding angle of the first wind deflector unit 1 according to the relationship between the wind speed of each of the two or more regions and the average wind speed value.

Specifically, each zone is provided with a wind speed detector. When the wind sweeping action instruction is not received, the motor control module obtains the wind speed average value beta of the wind speed of each area according to the wind speed fed back by the wind speed detectors of each area; judging whether the wind speed values eta 1, eta 2 and … … of the regions N1, N2 and … … are equal to the wind speed average value beta or not, namely judging the wind speed value eta of the i-th region_iAnd whether the current wind guiding angle is equal to beta or not is judged, and the current wind guiding angle of the first wind guiding plate unit 1 is adjusted according to the judgment result.

When the air conditioner runs, automatically detecting the wind speed according to default of a set control method; after the motor module automatically detects the wind speeds eta of all the regions, the wind speed average value beta is obtained, when the wind speeds eta of all the regions on the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3) are larger than (or smaller than or equal to) the wind speed average value beta, the motor control module independently controls the motors of all the regions to rotate according to the different wind speeds of all the regions, so that the angles of the air deflectors of all the regions are controlled, the air flow distribution is guided, the high wind speed of the rear side plate is synchronously guided to the surface of the heat exchanger (such as the heat exchanger 8 in the figure 3), and the surface wind speed of the heat exchanger (such as the heat exchanger 8 in the figure 3) is improved; the purposes of adjusting the surface wind speed uniformity of a heat exchanger (such as the heat exchanger 8 in the figure 3) and increasing the wind speed are achieved synchronously, and the heat exchange effect is enhanced.

In some embodiments, in step S320, the current wind guiding angle of the first wind deflector unit 1 is adjusted according to the relationship between the wind speed of each of two or more areas and the average wind speed, and the adjustment includes any one of the following adjustment situations:

the first adjustment scenario: and if the wind speed of at least one of the more than two areas is equal to the average wind speed value, controlling the current wind guide angle of the wind guide plate corresponding to the at least one area to be maintained at a set angle.

In particular, the wind speed value η detected if a certain region or a plurality of regions are synchronized_iIf the wind speed is equal to the average wind speed value beta, the motor control module controls the stepping motor in the area not to operate, and the air deflector in the area maintains the original state (the default horizontal state is maintained in the first detection).

The second adjustment scenario: if the wind speed of any one of the more than two areas is smaller than the average wind speed, controlling the current wind guiding angle of the wind deflector corresponding to the area to be increased so as to deflect the wind deflector corresponding to the area towards the heat exchanger 8 and guide the airflow to flow towards the heat exchanger 8.

Specifically, if the wind speed value eta detected in a certain area_iWhen the wind speed average value is not equal to the wind speed average value beta, the motor control module controls the stepping motor in the area to act to drive the air deflector in the area to rotate so as to enable the wind speed eta in the area to rotate_iAnd the current latest calculated wind speed average value beta is approached. Wind speed value eta as detected when a certain region_iIf the wind speed average value beta is less than the wind speed average value beta, the motor control module automatically controls the motor in the area to rotate, the opening angle of the air deflector in the area is adjusted to increase the wind speed, namely the air deflector in the area is controlled to deflect towards the direction of the heat exchanger (such as the heat exchanger 8 in the figure 3), and the airflow is guided to flow towards the direction of the heat exchanger (such as the heat exchanger 8 in the figure 3), at the moment, the wind speed detector synchronously detects the wind speed value eta of the air deflector in the area after the opening angle is adjusted_iAnd sending a signal to a motor control module, and adjusting the opening angle of an air deflector in the area to obtain a wind speed value eta_iAnd when the required value (namely the currently and newly calculated wind speed average value beta) is reached, the motor is controlled to stop moving.

The third adjustment case: and if the wind speed of any one of the more than two areas is greater than the average wind speed, controlling the current wind guiding angle of the wind guide plate corresponding to the area to be adjusted to be small, and enabling the airflow to flow towards other areas adjacent to the area.

Specifically, the wind speed value eta detected in a certain area_iThe opening angle of the air deflector in the area is adjusted to reduce the wind speed, so that the airflow flows to the area beside the area, and the effect of increasing the wind speed of the nearby area is achieved. For example: the wind speed value eta detected when the second region is_iThe wind speed is reduced by adjusting the opening angle of the second air deflector, so that the air flow flows to the side area, and the effect of increasing the wind speed of the nearby area is achieved. The side area is a side area of the second area, such as the first area, the third area, the fourth area, the fifth area, and so on.

In some embodiments, when a wind sweeping motion command sent by a user is not received, the adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed in step S130 further includes: and adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed.

With reference to the flowchart of fig. 10, a specific process of the second process of adjusting the current wind guiding angle of the first wind deflector unit 1 according to the wind speed in step S130 is further described, where the process includes: step S410 and step S420.

Step S410, after adjusting the current wind guiding angle of the first wind deflector unit 1, re-determining the wind speed average value of the wind speeds in the two or more areas, and re-determining the relationship between the wind speed of each of the two or more areas and the wind speed average value.

Step S420, re-adjusting the current wind guiding angle of the first wind deflector unit 1 according to the re-determined relationship between the wind speed of each of the two or more areas and the average wind speed value.

Specifically, after the wind guiding angle of the first wind deflector unit is adjusted each time, the wind speed value η of each region detected in real time is determined again_iThe wind speed average β is recalculated. The opening angle of the air deflector is adjusted in real time through the control, the air deflector is circularly reciprocated, the average value of the detected air speed is continuously updated so as to achieve the aim of uniformity of the air speed of each area, the high-speed area 15 of the rear side plate is synchronously utilized, and the heat exchange effect is improved.

Since the processing and functions implemented by the method of this embodiment substantially correspond to the embodiments, principles and examples of the air conditioner, reference may be made to the related descriptions in the foregoing embodiments without being detailed in the description of this embodiment.

Through a large number of tests, the technical scheme of the embodiment is adopted, the first air deflector unit is arranged between the fan and the heat exchanger of the split floor type air conditioner, and the air deflection angle of the first air deflector unit is adjusted according to the detected air speed so as to guide air flow distribution, so that the air speed distribution on the surface of the heat exchanger is uniform, the problem of non-uniform air speed distribution on the surface of the heat exchanger can be solved, and the air speed and the air volume on the surface of the heat exchanger can be reasonably distributed.

In conclusion, it is readily understood by those skilled in the art that the advantageous modes described above can be freely combined and superimposed without conflict.

The above description is only an example of the present invention, and is not intended to limit the present invention, and various modifications and changes may be made to the present invention by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (13)

1. A control apparatus of an air conditioner, characterized in that the air conditioner includes: a first air deflector unit (1); the first air deflector unit (1) is arranged between a fan (4) and a heat exchanger (8) of the air conditioner, and the current air deflecting angle of the first air deflector unit (1) can be adjusted; the first air deflection unit (1) comprising: more than two air deflectors; the control device of the air conditioner comprises: a detection unit and a control unit; wherein, the first and the second end of the pipe are connected with each other,

the control unit is configured to control the current air guide angle of the first air deflector unit (1) to be at a set angle under the condition that the air conditioner is started and operated;

the detection unit is configured to detect the wind speed of the lower surface of the heat exchanger (8) in the process of operating the air conditioner; the air deflectors are more than two, and correspondingly divide the surface of the heat exchanger (8) into more than two areas;

the control unit is configured to adjust the current wind guiding angle of the first wind deflector unit (1) according to the wind speed so as to guide the airflow distribution on the surface of the heat exchanger (8); each air deflector of the more than two air deflectors can guide air to a corresponding area on the surface of the heat exchanger (8);

further comprising:

the control unit is further configured to determine whether a wind sweeping action instruction sent by a user is received before the current wind guiding angle of the first wind deflector unit (1) is adjusted according to the wind speed; the wind sweeping action command comprises: a first adjusting instruction capable of adjusting the current air guide angle of the first air guide plate unit (1); and (c) a second step of,

under the condition that a wind sweeping action instruction sent by a user is not received, adjusting the current wind guiding angle of the first wind deflector unit (1) according to the wind speed;

under the condition that a wind sweeping action instruction sent by a user is received, adjusting the current wind guide angle of the first wind guide plate unit (1) according to the wind sweeping action instruction so as to enable the first wind guide plate unit (1) and a second wind guide plate unit (7) at the air outlet of the air conditioner to form a double wind guide phenomenon, and adjusting the path of airflow output from the outlet of the air conditioner fan (4) to the air outlet of the air conditioner to flow through the first wind guide plate unit (1) and the second wind guide plate unit (7);

wherein, under the condition that receives the action command of sweeping the wind that the user sent, sweep the wind action command, still include: and a second adjusting instruction capable of adjusting the current wind guide angle of the second wind guide plate unit (7).

2. The control device of the air conditioner according to claim 1, wherein the control unit adjusts a current wind guiding angle of the first wind deflector unit (1) according to the wind speed, and includes:

determining an average wind speed value of wind speeds of two or more of the regions, and determining a relation between the wind speed of each of the two or more of the regions and the average wind speed value;

and adjusting the current wind guide angle of the first wind deflector unit (1) according to the relation between the wind speed of each of more than two areas and the average wind speed value.

3. The control device of an air conditioner according to claim 2, wherein the control unit adjusts the current wind guiding angle of the first air guiding plate unit (1) according to a relationship between the wind speed of each of two or more of the zones and the average wind speed, and includes:

if the wind speed of at least one of the more than two areas is equal to the average wind speed, controlling the current wind guiding angle of the wind deflector corresponding to the at least one area to be maintained at a set angle;

if the wind speed of any one of the more than two areas is smaller than the average wind speed, controlling the current wind guide angle of the wind guide plate corresponding to the area to be increased so as to deflect the wind guide plate corresponding to the area towards the heat exchanger (8) and guide the airflow to flow towards the heat exchanger (8);

and if the wind speed of any one of the more than two areas is greater than the average wind speed, controlling the current wind guiding angle of the wind guide plate corresponding to the area to be adjusted to be small, and enabling the airflow to flow towards other areas adjacent to the area.

4. The control device of claim 2, wherein the control unit adjusts a current wind guiding angle of the first wind deflector unit (1) according to the wind speed, and further comprises:

after the current wind guiding angle of the first wind deflector unit (1) is adjusted, re-determining the wind speed average value of the wind speeds of more than two areas, and re-determining the relation between the wind speed of each of the more than two areas and the wind speed average value;

and re-adjusting the current wind guide angle of the first wind deflector unit (1) according to the re-determined relation between the wind speed of each of the more than two areas and the average wind speed value.

5. The control device of an air conditioner according to claim 2, wherein the first air guiding plate unit (1) further comprises: the motor is matched with each air deflector; the control unit controls the current air guide angle of one air guide plate matched with one motor by controlling the rotation of one motor.

6. The control device of an air conditioner according to claim 5, wherein the first air guiding plate unit (1) further comprises: a crankshaft support rod (10), a crankshaft (11) and a motor support rod (14); wherein the content of the first and second substances,

the crankshaft support rod (10) and the motor support rod (14) are arranged in parallel; the air deflectors are arranged between the crankshaft support rod (10) and the motor support rod (14) in parallel;

-one said crankshaft (11) arranged between said crankshaft support rod (10) and a first end of one said air deflector; the motor is arranged between the motor supporting rod (14) and the second end of the air deflector.

7. The control device of claim 2, wherein at least one of the two or more air deflectors includes: a honeycomb air deflector (13).

8. An air conditioner, comprising: the control device of the air conditioner according to any one of claims 1 to 7.

9. A control method of an air conditioner according to claim 8, wherein the air conditioner comprises: a first air deflector unit (1); the first air deflector unit (1) is arranged between a fan (4) and a heat exchanger (8) of the air conditioner, and the current air deflection angle of the first air deflector unit (1) can be adjusted; the control method of the air conditioner comprises the following steps:

under the condition that the air conditioner is started and operated, controlling the current air guide angle of the first air guide plate unit (1) to be at a set angle;

detecting the wind speed of the lower surface of the heat exchanger (8) in the running process of the air conditioner;

and adjusting the current wind guide angle of the first wind deflector unit (1) according to the wind speed so as to guide the airflow distribution on the surface of the heat exchanger (8).

10. The control method of an air conditioner according to claim 9, further comprising:

before the current wind guide angle of the first wind deflector unit (1) is adjusted according to the wind speed, whether a wind sweeping action instruction sent by a user is received or not is determined; the wind sweeping action command comprises: a first adjusting instruction capable of adjusting the current air guide angle of the first air guide plate unit (1); and the number of the first and second groups,

under the condition that a wind sweeping action instruction sent by a user is not received, adjusting the current wind guiding angle of the first wind deflector unit (1) according to the wind speed;

under the condition that a wind sweeping action instruction sent by a user is received, adjusting the current wind guide angle of the first wind guide plate unit (1) according to the wind sweeping action instruction so as to enable the first wind guide plate unit (1) and a second wind guide plate unit (7) at the air outlet of the air conditioner to form a double wind guide phenomenon, and adjusting the path of airflow output from the outlet of the air conditioner fan (4) to the air outlet of the air conditioner to flow through the first wind guide plate unit (1) and the second wind guide plate unit (7);

wherein, under the condition that receives the action command of sweeping the wind that the user sent, the action command of sweeping the wind still includes: and a second adjusting instruction capable of adjusting the current air guide angle of the second air guide plate unit (7).

11. The control method of an air conditioner according to claim 9 or 10, wherein the first air deflection unit (1) includes: more than two air deflectors; the air deflectors are more than two, and correspondingly divide the surface of the heat exchanger (8) into more than two areas; each air deflector of the more than two air deflectors can guide air to a corresponding area on the surface of the heat exchanger (8);

adjusting the current wind guiding angle of the first wind deflector unit (1) according to the wind speed, wherein the method comprises the following steps:

determining an average wind speed value of wind speeds of two or more of the regions, and determining a relation between the wind speed of each of the two or more of the regions and the average wind speed value;

and adjusting the current wind guide angle of the first wind deflector unit (1) according to the relation between the wind speed of each of more than two areas and the average wind speed value.

12. The method of claim 11, wherein adjusting the current wind guiding angle of the first wind deflector unit (1) according to the relationship between the wind speed of each of the two or more zones and the average wind speed comprises:

if the wind speed of at least one of the more than two areas is equal to the average wind speed, controlling the current wind guiding angle of the wind deflector corresponding to the at least one area to be maintained at a set angle;

if the wind speed of any one of the more than two areas is smaller than the average wind speed, controlling the current wind guide angle of the wind guide plate corresponding to the area to be increased so as to deflect the wind guide plate corresponding to the area towards the heat exchanger (8) and guide the airflow to flow towards the heat exchanger (8);

and if the wind speed of any one of the more than two areas is greater than the average wind speed, controlling the current wind guiding angle of the wind guide plate corresponding to the area to be adjusted to be small, and enabling the airflow to flow towards other areas adjacent to the area.

13. The method of claim 11, wherein the adjusting the current wind guiding angle of the first wind deflector unit (1) according to the wind speed further comprises:

after the current wind guiding angle of the first wind deflector unit (1) is adjusted, re-determining the wind speed average value of the wind speeds of more than two areas, and re-determining the relation between the wind speed of each of the more than two areas and the wind speed average value;

and readjusting the current wind guiding angle of the first wind deflector unit (1) according to the relationship between the re-determined wind speed of each of the more than two areas and the average wind speed value.

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