CN113932367A - Air conditioner heating control method and device, air conditioner and computer storage medium - Google Patents

Abstract

The invention provides an air conditioner heating control method, an air conditioner heating control device, an air conditioner and a computer storage medium, wherein an air outlet pipeline and a bottom air outlet which are extended to the bottom of a room are additionally arranged on the air conditioner, and the method comprises the following steps: s1: judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode; s2: starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner; s3: and switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the temperature parameter of the air conditioner. By the air conditioner heating control method and device, the air conditioner and the computer storage medium, under the heating working condition in winter, the bottom air supply function can be used as an auxiliary means to be combined with the conventional air supply of the air conditioner, the effect of quickly heating a room is achieved, and the thermal comfort experience of a user is improved.

Description

Air conditioner heating control method and device, air conditioner and computer storage medium

Technical Field

The invention relates to the technical field of air conditioning, in particular to an air conditioner heating control method, an air conditioner heating control device, an air conditioner and a computer storage medium.

Background

Most of the existing air-conditioning hanging machines are installed above rooms, and under the heating working condition in winter, hot air blown out by an air conditioner can be suspended above the rooms, so that the heating effect and the user experience are influenced. The concrete points are as follows:

1) when the air conditioner heats in winter, the hot air can float upwards and cannot fall to the ground, and a user cannot feel the hot air in a short time when the air conditioner is started, so that the actual heating efficiency of the air conditioner is reduced;

2) when a user sits or lies in a room, the user is far away from hot air blown out by the air conditioner, and even if the hanging part of the air conditioner reaches the set heating temperature, the sensible temperature felt by the user is still low.

Disclosure of Invention

In view of the above, the technical problems to be solved by the present invention are: the first aspect is to provide an air conditioner heating control method, which improves the heating effect of the air conditioner under the heating working condition in winter and the thermal comfort experience of a user.

In order to solve the technical problem of the first aspect, the invention provides a heating control method for an air conditioner, wherein an air outlet pipeline and a bottom air outlet which are extended to the bottom of a room are additionally arranged on the air conditioner, and the method comprises the following steps:

s1: judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode;

s2: starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner;

s3: and switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the temperature parameter of the air conditioner.

By the air conditioner heating control method, under the heating working condition in winter, the bottom air supply function can be used as an auxiliary means to be combined with the conventional air supply of the air conditioner, so that the effect of quickly heating a room is achieved, and the thermal comfort experience of a user is improved. And under the summer refrigeration working condition, the bottom air supply function is not allowed to be started, so that the cold air is prevented from directly blowing to a human body, and the human body refrigeration comfort is not good. Meanwhile, when the bottom air supply function has multiple bottom air supply modes, the starting and stopping of the bottom air supply function and the switching of the bottom air supply modes can further improve the heating effect of the air conditioner under the heating working condition in winter and the thermal comfort experience of a user.

Preferably, step S1 includes the following specific operation steps:

s11: judging whether the air conditioner starting mode is a heating mode or not;

s12: if yes, go to step S13; if not, go to step S14;

s13: the bottom air supply function is allowed to be started, and the step S2 is executed;

s14: the bottom air supply function is not allowed to be started, and the normal air supply operation is kept.

As long as the heating mode is not adopted, the bottom air supply function is not allowed to be started, so that the bottom air supply function is ensured not to be started by mistake.

Preferably, step S14 includes the following specific operation steps:

s141: judging whether the starting time length of the current starting mode is greater than or equal to a first preset time length or not;

s142: if yes, go to step S143; if not, returning to the step S11;

s143: the bottom air supply function is not allowed to be started, and the normal air supply operation is kept.

The problem that the air conditioner cannot start the bottom air supply function due to the fact that the user does not select the heating mode in a short time when the air conditioner is started in winter can be solved.

Preferably, the first preset time period is 10 minutes.

The first preset time can be set as required, the first preset time is set to be 10 minutes, the problem that the air conditioner cannot start the bottom air supply function due to the fact that a user does not select the heating mode for a short time can be fully avoided, the rationality that other starting modes of the air conditioner are kept for long-time operation is fully taken into account, the situation that the user forgets to select the heating mode for a short time is basically eliminated, and further whether the bottom air supply function is allowed to be started or not is not required to be in a controlled judgment state all the time, and the air conditioner can achieve better energy-saving operation.

Preferably, step S2 includes the following specific operation steps:

s21: judging whether T1< T and/or T2< T are met, wherein T1 is the indoor environment temperature detected by the air conditioner inner ring sensor, T2 is the bottom air outlet temperature, and T is the set temperature of the air conditioner;

s22: if yes, go to step S23; if not, go to step S24;

s23: starting and selecting an air conditioner bottom air supply mode according to the delta T, wherein the delta T is T-T2;

s24: the bottom air supply function is not started or closed, and the normal air supply operation is kept.

The temperature judgment of the step 21 can prevent the false start of the bottom air supply function caused by the false start of the heating mode in summer; and step 23 is used for further judging the temperature difference delta T, so that not only can the starting condition of the bottom air supply function be more accurately determined in a refining way, but also the bottom air supply mode can be further selected according to the temperature difference delta T while the bottom air supply function is started, and therefore the quick heating effect and the user thermal comfort experience of the air conditioner under the heating working condition in winter can be further improved.

Preferably, step S23 includes the following specific operation steps:

s231: judging whether the delta T is less than or equal to a first preset temperature difference value delta T1;

s232: if yes, return to step S24; if not, judging whether the delta T is less than or equal to a second preset temperature difference value delta T2;

s233: if yes, go to step S235; if not, judging whether the delta T is smaller than a third preset temperature difference value delta T3;

s234: if yes, go to step S236; if not, go to step S237;

s235: starting a low-wind-speed bottom air supply mode;

s236: starting a middle wind speed bottom air supply mode;

s237: starting a high-wind-speed bottom air supply mode;

wherein Δ T1< Δ T2< Δ T3.

When the delta T is greater than the delta T1, the selection of the bottom air supply mode can be matched with the difference degree of the temperature difference delta T, and the thermal comfort experience of a user is better while the quick heating effect is improved; on the contrary, when the delta T is less than or equal to the delta T1, the current indoor temperature is higher, and the bottom air supply function can ensure the quick heating effect of the air conditioner and the thermal comfort experience of the user without being started, so that the energy-saving operation of the air conditioner is facilitated.

Preferably, when any one of steps S235, S236, and S237 is executed, step S23 further includes the following specific operation steps:

s231': judging whether the running time of the current bottom air supply mode is greater than or equal to a second preset time;

s232': if yes, return to step S21; if not, the operation of the current bottom air supply mode is kept.

As one of the preferred embodiments of the present invention, the turn-off condition of the bottom blowing function can be set individually according to the personal preference of the user, and the preferred embodiment is more suitable for the situation that the requirement of the user on thermal comfort is relatively high. In addition, for the switching of the bottom air supply mode, the bottom air supply mode can be basically matched with the air conditioner temperature parameter change, the hysteresis effect brought by the different bottom air supply modes to the air conditioner temperature parameter change is considered, and the user thermal comfort experience is better.

The technical problems to be solved by the invention are as follows: a second aspect provides an air conditioner heating control apparatus, and/or a third aspect provides an air conditioner, and/or a fourth aspect provides a computer readable storage medium, which improves heating effect and user thermal comfort experience of the air conditioner in winter heating conditions.

In order to solve the technical problem of the second aspect, the present invention provides an air conditioner heating control device, configured to execute the method according to any one of the embodiments of the first aspect, where the device includes:

a judging module: the air conditioner is used for judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode;

a control module: the air conditioner is used for starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner when the judgment result of the judgment module is yes;

an execution module: and the air conditioner is used for switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the air conditioner temperature parameter.

To solve the technical problem of the third aspect, the present invention provides an air conditioner, including a computer-readable storage medium storing a computer program and a processor, where the computer program is read by the processor and executed to implement the method according to any one of the embodiments of the first aspect.

To solve the technical problem of the fourth aspect, the present invention provides a computer-readable storage medium, which stores a computer program, and when the computer program is read and executed by a processor, the computer program implements the method according to any one of the embodiments of the first aspect.

Compared with the prior art, the air conditioner heating control method, the air conditioner heating control device, the air conditioner and the computer storage medium have the following beneficial effects:

1) under the heating working condition in winter, the bottom air supply function can be used as an auxiliary means to be combined with the conventional air supply of the air conditioner, so that the effect of quickly heating a room is achieved, and the heat comfort experience of a user is improved;

2) under the refrigeration working condition in summer, the bottom air supply function is not allowed to be started, so that cold air is prevented from being directly blown to a human body, and the refrigeration comfort of the human body is not good;

3) the bottom air supply function has multiple bottom air supply modes, and the start and stop of the bottom air supply function and the switching of the bottom air supply mode can further improve the heating effect of the air conditioner under the heating working condition in winter and the thermal comfort experience of a user.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention, illustrate embodiments of the invention and together with the description serve to explain the invention and are not to limit the invention. In the drawings:

fig. 1 is a schematic flow chart of an air conditioner heating control method according to embodiment 1 of the present invention.

Detailed Description

In order to make the aforementioned objects, technical solutions and advantages of the present invention more comprehensible, the present invention is described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are only some of the embodiments constituting the present invention, and are not intended to limit the present invention, and the embodiments and features of the embodiments may be combined with each other without conflict.

Example 1

As shown in fig. 1, the present invention provides a heating control method for an air conditioner, in which an air outlet duct and a bottom air outlet are added to the air conditioner, the air conditioner is extended to the bottom of a room, and the method includes the following steps:

s1: judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode;

s2: starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner;

s3: and switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the temperature parameter of the air conditioner.

Specifically, the air conditioner has a bottom air supply function due to the additionally arranged bottom air outlet, and the bottom air supply function can be used as an auxiliary means to be combined with conventional air supply of the air conditioner under the heating working condition in winter, so that at least part of air conditioner hot air is blown out from the bottom of a room; with the fact that the hot air floats upwards from the bottom of the room continuously, the effect of quickly heating the room can be achieved, and the thermal comfort experience of a user is improved. And under the summer refrigeration working condition, the bottom air supply function is not allowed to be started, so that the cold air is prevented from directly blowing to a human body, and the human body refrigeration comfort is not good. Meanwhile, when the bottom air supply function has multiple bottom air supply modes, the starting and stopping of the bottom air supply function and the switching of the bottom air supply modes can further improve the heating effect of the air conditioner under the heating working condition in winter and the thermal comfort experience of a user.

Preferably, step S1 includes the following specific operation steps:

s11: judging whether the air conditioner starting mode is a heating mode or not;

s12: if yes, go to step S13; if not, go to step S14;

s13: the bottom air supply function is allowed to be started, and the step S2 is executed;

s14: the bottom air supply function is not allowed to be started, and the normal air supply operation is kept.

Specifically, only when the air conditioner is in the heating mode, the bottom air supply function is allowed to be started, and other modes such as the cooling mode, the defrosting mode and the dehumidifying mode are not allowed to be started as long as the air conditioner is not in the heating mode, so that the bottom air supply function is ensured not to be started by mistake.

Preferably, step S14 includes the following specific operation steps:

s141: judging whether the starting time length of the current starting mode is greater than or equal to a first preset time length or not;

s142: if yes, go to step S143; if not, returning to the step S11;

s143: the bottom air supply function is not allowed to be started, and the normal air supply operation is kept.

Specifically, in the process of determining whether the bottom blowing function is allowed to be turned on, the turning-on mode of the air conditioner may be a variable value updated in real time under a certain condition, or in other words, the turning-on period of the air conditioner is a time period and is not limited to only one turning-on moment. For example, if the first preset time period is set to 10 minutes, after the air conditioner is started, the air conditioner is still in the start period as long as the continuous start time period of the air conditioner in the same non-heating mode does not exceed 10 minutes, and at this time, the air conditioner can judge whether the bottom air supply function is allowed to be started again as long as the air conditioner receives a new mode switching instruction. Therefore, the problem that the air conditioner cannot start the bottom air supply function due to the fact that the user does not select the heating mode in a short time when the air conditioner is started in winter can be avoided.

Preferably, the first preset time period is 10 minutes.

Specifically, the first preset time period can be set as required, for example, any one time period of 5-20 minutes can be set, and the first preset time period is set to 10 minutes, so that the problem that the air conditioner cannot start the bottom air supply function due to the fact that a user does not select the heating mode for a short time can be sufficiently avoided, and the rationality that other starting modes of the air conditioner are kept for long-time operation is fully taken into account. Namely, when the air conditioner starting mode is the non-heating mode and the non-heating mode is continuously started for more than 10 minutes, the situation that the current non-heating starting mode is just needed by a user is basically eliminated, the situation that the user forgets to select the heating mode for a short time is basically eliminated, and further whether the bottom air supply function is allowed to be started or not is not required to be in a controlled judgment state all the time, so that the air conditioner is favorable for realizing better energy-saving operation.

Preferably, step S2 includes the following specific operation steps:

s21: judging whether T1< T and/or T2< T are met, wherein T1 is the indoor environment temperature detected by the air conditioner inner ring sensor, T2 is the bottom air outlet temperature, and T is the set temperature of the air conditioner;

s22: if yes, go to step S23; if not, go to step S24;

s23: starting and selecting an air conditioner bottom air supply mode according to the delta T, wherein the delta T is T-T2;

s24: the bottom air supply function is not started or closed, and the normal air supply operation is kept.

Specifically, the air conditioner temperature parameters include an indoor environment temperature T1, a bottom air outlet temperature T2, an air conditioner set temperature T, and a difference value Δ T (hereinafter referred to as "temperature difference Δ T") between the air conditioner set temperature and the bottom air outlet temperature, where T1 is the indoor environment temperature detected by the air conditioner inner ring sensor in the prior art, a temperature measurement point of the indoor environment temperature will be located near the conventional air outlet of the air conditioner, and a temperature measurement point of T2 will be located at the bottom air outlet. When T1 is more than or equal to T and T2 is more than or equal to T, the current room temperature is high, the bottom air supply function is allowed to be started but does not need to be started, or the bottom air supply function needs to be closed after the bottom air supply function is started; on the contrary, the bottom air supply function may need to be started, and the air conditioner bottom air supply mode needs to be started and selected according to the further judgment of the delta T.

Since both T1 and T2 are significantly greater than T in summer, the temperature determination of step 21 prevents the user from mistakenly starting the bottom blowing function due to the mistaken starting of the heating mode in summer; and step 23 is used for further judging the temperature difference delta T, so that not only can the starting condition of the bottom air supply function be more accurately determined in a refining way, but also the bottom air supply mode can be further selected according to the temperature difference delta T while the bottom air supply function is started, and therefore the quick heating effect and the user thermal comfort experience of the air conditioner under the heating working condition in winter can be further improved.

Preferably, step S23 includes the following specific operation steps:

s231: judging whether the delta T is less than or equal to a first preset temperature difference value delta T1;

s232: if yes, return to step S24; if not, judging whether the delta T is less than or equal to a second preset temperature difference value delta T2;

s233: if yes, go to step S235; if not, judging whether the delta T is smaller than a third preset temperature difference value delta T3;

s234: if yes, go to step S236; if not, go to step S237;

s235: starting a low-wind-speed bottom air supply mode;

s236: starting a middle wind speed bottom air supply mode;

s237: starting a high-wind-speed bottom air supply mode;

wherein Δ T1< Δ T2< Δ T3.

Specifically, after the bottom air supply function is started, the three air outlet speeds of the low air speed a1, the medium air speed a2 and the high air speed A3 can be further detailed according to the size of the bottom air outlet speed a, wherein a1 is greater than a2 and is less than A3, and correspondingly, the bottom air supply function has three bottom air supply modes of the low air speed, the medium air speed and the high air speed after being started. Δ T1, Δ T2, and Δ T3 may be set to 3 ℃, 5 ℃, 10 ℃ in sequence, for example, and further when Δ T > Δ T1, the selection of the bottom blowing mode may be matched with the difference degree of the temperature difference Δ T, so that the user experiences better thermal comfort while improving the quick heating effect; on the contrary, when the delta T is less than or equal to the delta T1, the current indoor temperature is higher, and the bottom air supply function can ensure the quick heating effect of the air conditioner and the thermal comfort experience of the user without being started, so that the energy-saving operation of the air conditioner is facilitated.

As one of the preferred embodiments of the present invention, when any one of steps S235, S236, and S237 is executed, step S23 further includes the following specific operation steps:

s231': judging whether the running time of the current bottom air supply mode is greater than or equal to a second preset time;

s232': if yes, return to step S21; if not, the operation of the current bottom air supply mode is kept.

As another preferred embodiment of the present invention, when any one of steps S235, S236, and S237 is executed, step S23 further includes the following specific operation steps:

s231': judging whether the running time of the current bottom air supply mode is greater than or equal to a second preset time;

s232': if yes, return to step S231; if not, the operation of the current bottom air supply mode is kept.

Specifically, the second preset time period may be set to 15 minutes, for example, after the current bottom blowing mode has been continuously turned on for 15 minutes, the temperature determination in step S21 may be returned again, or the temperature difference determination in step S231 may be directly returned again, where the above two preferred embodiments are different only in that the turning-off condition of the bottom blowing function (hereinafter, referred to as "auxiliary heat turning-off condition") is slightly different, and may be specifically set individually according to the personal preference of the user. For example, when the requirement of the user for thermal comfort is relatively high, the auxiliary thermal shutdown condition may be set to "T1 ≧ T and T2 ≧ T", that is, corresponding to the first preferred embodiment; when the user's requirement for thermal comfort is relatively low, the secondary thermal shutdown condition may be set to "Δ T ≦ Δ T1", i.e., corresponding to the second preferred embodiment.

The switching of the bottom air supply mode is the same regardless of the first preferred embodiment or the second preferred embodiment, that is, the current bottom air supply mode needs to be adjusted in time according to the timing change of the air conditioner temperature parameter, wherein the timing interval, that is, the second preset time duration, is preferably set to 15 minutes, so that the bottom air supply mode can be basically matched with the change of the air conditioner temperature parameter, and the hysteresis effect of different bottom air supply modes on the change of the air conditioner temperature parameter is fully considered, and therefore, the thermal comfort experience of a user is better.

Finally, it should be noted that, as will be understood by those skilled in the art, step S24 includes two layers, where the first layer is: when the bottom air supply function is in the unopened state, the bottom air supply function is not opened, and the conventional air supply operation is kept; the second layer means: and when the bottom air supply function is in the opening state, the bottom air supply function is closed, and the conventional air supply operation is kept.

Example 2

The present invention also provides an air conditioner heating control apparatus for performing the method as described in embodiment 1, the apparatus including:

a judging module: the air conditioner is used for judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode;

a control module: the air conditioner is used for starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner when the judgment result of the judgment module is yes;

an execution module: and the air conditioner is used for switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the air conditioner temperature parameter.

The present invention also provides an air conditioner comprising a computer readable storage medium storing a computer program and a processor, the computer program being read and executed by the processor to implement the method as described in embodiment 1.

The invention also provides a computer-readable storage medium, which stores a computer program that, when read and executed by a processor, implements the method as described in embodiment 1.

Specifically, as will be understood by those skilled in the art, the air-conditioning heating control device, the air conditioner, and the computer-readable storage medium provided in embodiment 2 may be implemented by a combination of hardware and software to implement the method described in embodiment 1. For information interaction, execution process, and the like of any one of the air-conditioning heating control device, the air-conditioner, and the computer-readable storage medium, reference may be made to the description of the air-conditioning heating control method in embodiment 1, and details are not repeated here.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (10)

1. The air conditioner heating control method is characterized in that an air outlet pipeline and a bottom air outlet which are extended to the bottom of a room are additionally arranged on the air conditioner, and the method comprises the following steps:

s1: judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode;

s2: starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner;

s3: and switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the temperature parameter of the air conditioner.

2. An air conditioner heating control method as claimed in claim 1, wherein step S1 includes the following specific operation steps:

s11: judging whether the air conditioner starting mode is a heating mode or not;

s12: if yes, go to step S13; if not, go to step S14;

s13: the bottom air supply function is allowed to be started, and the step S2 is executed;

s14: the bottom air supply function is not allowed to be started, and the normal air supply operation is kept.

3. An air conditioner heating control method as claimed in claim 2, wherein step S14 includes the following specific operation steps:

s141: judging whether the starting time length of the current starting mode is greater than or equal to a first preset time length or not;

s142: if yes, go to step S143; if not, returning to the step S11;

s143: the bottom air supply function is not allowed to be started, and the normal air supply operation is kept.

4. An air conditioner heating control method as claimed in claim 3, wherein the first preset time period is 10 minutes.

5. An air conditioner heating control method as claimed in any one of claims 1-4, wherein step S2 includes the following specific operation steps:

s21: judging whether T1< T and/or T2< T are met, wherein T1 is the indoor environment temperature detected by the air conditioner inner ring sensor, T2 is the bottom air outlet temperature, and T is the set temperature of the air conditioner;

s22: if yes, go to step S23; if not, go to step S24;

s23: starting and selecting an air conditioner bottom air supply mode according to the delta T, wherein the delta T is T-T2;

s24: the bottom air supply function is not started or closed, and the normal air supply operation is kept.

6. An air conditioner heating control method as claimed in claim 5, wherein step S23 includes the following specific operation steps:

s231: judging whether the delta T is less than or equal to a first preset temperature difference value delta T1;

s232: if yes, return to step S24; if not, judging whether the delta T is less than or equal to a second preset temperature difference value delta T2;

s233: if yes, go to step S235; if not, judging whether the delta T is smaller than a third preset temperature difference value delta T3;

s234: if yes, go to step S236; if not, go to step S237;

s235: starting a low-wind-speed bottom air supply mode;

s236: starting a middle wind speed bottom air supply mode;

s237: starting a high-wind-speed bottom air supply mode;

wherein Δ T1< Δ T2< Δ T3.

7. An air conditioner heating control method as claimed in claim 6, wherein when any one of steps S235, S236 and S237 is executed, step S23 further includes the following specific operation steps:

s231': judging whether the running time of the current bottom air supply mode is greater than or equal to a second preset time;

s232': if yes, return to step S21; if not, the operation of the current bottom air supply mode is kept.

8. An air conditioning heating control apparatus for performing the method of any one of claims 1-7, the apparatus comprising:

a judging module: the air conditioner is used for judging whether the air supply function at the bottom of the air conditioner is allowed to be started or not according to the air conditioner starting mode;

a control module: the air conditioner is used for starting and selecting an air supply mode at the bottom of the air conditioner according to the temperature parameter of the air conditioner when the judgment result of the judgment module is yes;

an execution module: and the air conditioner is used for switching the bottom air supply mode or closing the bottom air supply function according to the running time of the bottom air supply mode and the air conditioner temperature parameter.

9. An air conditioner comprising a computer readable storage medium storing a computer program and a processor, the computer program being read and executed by the processor to implement the method of any one of claims 1-7.

10. A computer-readable storage medium, characterized in that it stores a computer program which, when read and executed by a processor, implements the method according to any one of claims 1-7.

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